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You will then receive an email that contains a secure link for resetting your password Email* If the address matches a valid account an email will be sent to __email__ with instructions for resetting your password Cancel ORIGINAL RESEARCH|Articles in Press A Single Dermatome Clinical Prediction Rule for Independent Walking 1 Year After Spinal Cord Injury * PDF [1 MB]PDF [1 MB] * Figures * Figure Viewer * Download Figures (PPT) * Save * Add To Online LibraryPowered ByMendeley * Add To My Reading List * Export Citation * Create Citation Alert * Share Share on * Twitter * Facebook * Linked In * Sina Weibo * Email * more * Reprints * Request * Top A SINGLE DERMATOME CLINICAL PREDICTION RULE FOR INDEPENDENT WALKING 1 YEAR AFTER SPINAL CORD INJURY * Andrew C. Smith, PT, DPT, PhD Andrew C. Smith Correspondence Corresponding author Andrew C. Smith, PT, DPT, PhD, Department of Physical Medicine and Rehabilitation, University of Colorado School of Medicine, Aurora, CO, USA. Contact Affiliations Department of Physical Medicine and Rehabilitation, University of Colorado School of Medicine, Aurora, CO Search for articles by this author * Christina Draganich, DO Christina Draganich Affiliations Department of Physical Medicine and Rehabilitation, University of Colorado School of Medicine, Aurora, CO Craig Hospital, Englewood, CO Search for articles by this author * Wesley A. Thornton, PT, DPT Wesley A. Thornton Affiliations Department of Physical Medicine and Rehabilitation, University of Colorado School of Medicine, Aurora, CO Search for articles by this author * Jeffrey C. Berliner, DO Jeffrey C. Berliner Affiliations Department of Physical Medicine and Rehabilitation, University of Colorado School of Medicine, Aurora, CO Search for articles by this author * Peter J. Lennarson, MD Peter J. Lennarson Affiliations Department of Neurosurgery, University of Colorado School of Medicine, Aurora, CO Search for articles by this author * Enrico Rejc, PhD Enrico Rejc Affiliations Department of Neurosurgery, University of Louisville School of Medicine, Louisville, KY Department of Medicine, University of Udine, Udine, Italy Search for articles by this author * Mitch Sevigny, MS Mitch Sevigny Affiliations Craig Hospital, Englewood, CO Search for articles by this author * * Susan Charlifue, PhD Susan Charlifue Affiliations Craig Hospital, Englewood, CO Search for articles by this author * Candace Tefertiller, PT, DPT, PhD Candace Tefertiller Affiliations Craig Hospital, Englewood, CO Search for articles by this author * Kenneth A. Weber II, DC, PhD Kenneth A. Weber II Affiliations Department of Anesthesiology, Perioperative and Pain Medicine, Stanford University School of Medicine, Palo Alto, CA Search for articles by this author * Show all authors Open AccessPublished:July 04, 2023DOI:https://doi.org/10.1016/j.apmr.2023.06.015 Plum Print visual indicator of research metrics PlumX Metrics * Social Media * Shares, Likes & Comments: 1 * Tweets: 6 see details Previous ArticleDifferent thumb positions in the tetraplegic hand Next ArticleMultiple Sustainable Benefits of a Rehabilitation Program in … * Abstract * Keywords * Methods * Results * Discussion * Conclusions * References * Article info * Figures * Tables * Related Articles ABSTRACT OBJECTIVE To derive and validate a simple, accurate CPR to predict future independent walking ability after SCI at the bedside that does not rely on motor scores and is predictive for those initially classified in the middle of the SCI severity spectrum. DESIGN Retrospective cohort study. Binary variables were derived, indicating degrees of sensation to evaluate predictive value of pinprick and light touch variables across dermatomes. The optimal single sensory modality and dermatome was used to derive our CPR, which was validated on an independent dataset. SETTING Analysis of SCI Model Systems dataset. PARTICIPANTS Individuals with traumatic SCI. The data of 3679 participants (N=3679) were included with 623 participants comprising the derivation dataset and 3056 comprising the validation dataset. INTERVENTIONS Not applicable. MAIN OUTCOME MEASURES Self-reported ability to walk both indoors and outdoors. RESULTS Pinprick testing at S1 over lateral heels, within 31 days of SCI, accurately identified future independent walkers 1 year after SCI. Normal pinprick in both lateral heels provided good prognosis, any pinprick sensation in either lateral heel provided fair prognosis, and no sensation provided poor prognosis. This CPR performed satisfactorily in the middle SCI severity subgroup. CONCLUSIONS In this large multi-site study, we derived and validated a simple, accurate CPR using only pinprick sensory testing at lateral heels that predicts future independent walking after SCI. KEYWORDS * Clinical prediction rule * Pinprick * Rehabilitation * Spinal cord injury * Walking LIST OF ABBREVIATIONS: AIS (American Spinal Injury Association Impairment Scale), CI (confidence interval), CPR (clinical prediction rule), ISNCSCI (International Standards for Neurological Classification of Spinal Cord Injury), NPV (negative predictive value), PPV (positive predictive value), SCI (spinal cord injury), SCIMS (Spinal Cord Injury Model Systems) The recovery of walking ability is a top priority early after traumatic spinal cord injury (SCI). 1 * Ditunno PL * Patrick M * Stineman M * Ditunno JF Who wants to walk? Preferences for recovery after SCI: a longitudinal and cross-sectional study. Spinal Cord. 2008; 46: 500-506 * Crossref * PubMed * Scopus (215) * Google Scholar Because this patient group is so heterogeneous in nature, predicting future independent walking ability is challenging. 2 * Pelletier-Roy R * Richard-Denis A * Jean S * et al. Clinical judgment is a cornerstone for validating and using clinical prediction rules: a head-to-head study on ambulation outcomes for spinal cord injured patients. Spinal Cord. 2021; 59: 1104-1110 * Crossref * PubMed * Scopus (1) * Google Scholar Clinical prediction rules (CPRs) have been derived to aid in this task. 3 * van Middendorp JJ * Hosman AJ * Donders ART * et al. A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury: a longitudinal cohort study. Lancet. 2011; 377: 1004-1010 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (183) * Google Scholar , 4 * Hicks KE * Zhao Y * Fallah N * et al. A simplified clinical prediction rule for prognosticating independent walking after spinal cord injury: a prospective study from a Canadian multicenter spinal cord injury registry. Spine J. 2017; 17: 1383-1392 * Abstract * Full Text * Full Text PDF * PubMed * Google Scholar , 5 * Jean S * Mac-Thiong JM * Jean MC * Dionne A * Bégin J * Richard-Denis A Early clinical prediction of independent outdoor functional walking capacity in a prospective cohort of traumatic spinal cord injury patients. Am J Phys Med Rehabil. 2021; 100: 1034-1041 * Crossref * PubMed * Scopus (1) * Google Scholar , 6 * Draganich C * Weber KA * Thornton WA * et al. Predicting outdoor walking 1 year after spinal cord injury: a retrospective, multisite external validation study. J Neurol Phys Ther. 2023; 47: 155-161 * Crossref * PubMed * Scopus (0) * Google Scholar However, problems with these CPRs include complex equations with multiple predictor variables limiting true clinical utility as well as suboptimal definitions of independent walking. 3 * van Middendorp JJ * Hosman AJ * Donders ART * et al. A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury: a longitudinal cohort study. Lancet. 2011; 377: 1004-1010 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (183) * Google Scholar , 7 * Wilson JR * Grossman RG * Frankowski RF * et al. A clinical prediction model for long-term functional outcome after traumatic spinal cord injury based on acute clinical and imaging factors. J Neurotrauma. 2012; 29: 2263-2271 * Crossref * PubMed * Scopus (131) * Google Scholar , 8 * Zörner B * Blanckenhorn WU * Dietz V * Curt A EM-SCI Study Group Clinical algorithm for improved prediction of ambulation and patient stratification after incomplete spinal cord injury. J Neurotrauma. 2010; 27: 241-252 * Crossref * PubMed * Scopus (0) * Google Scholar As an example, van Middendorp et al's CPR uses 5 predictor variables (1 age, 2 motor, and 3 sensory) that are then weighted and summed to first calculate the CPR score, the CPR score is then input into a logistical regression model (ie, sigmoid function) to calculate the probability of walking. 3 * van Middendorp JJ * Hosman AJ * Donders ART * et al. A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury: a longitudinal cohort study. Lancet. 2011; 377: 1004-1010 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (183) * Google Scholar Hicks et al simplified this CPR to only 3 predictor variables (1 age, 1 motor, and 1 sensory), but their CPR still requires calculating a weighted sum, which is then input into a logistical regression model (also sigmoid function) to calculate the probability of walking. 4 * Hicks KE * Zhao Y * Fallah N * et al. A simplified clinical prediction rule for prognosticating independent walking after spinal cord injury: a prospective study from a Canadian multicenter spinal cord injury registry. Spine J. 2017; 17: 1383-1392 * Abstract * Full Text * Full Text PDF * PubMed * Google Scholar A recent study found that the van Middendorp CPR provided clinical utility for only 45% of patients with traumatic SCI and also found that only 18% of experienced clinicians found this CPR useful for established prognosis. 9 * Everhart J * Somers M * Hibbs R * Worobey LA Clinical utility during inpatient rehabilitation of a clinical prediction rule for ambulation prognosis following spinal cord injury. J Spinal Cord Med. 2023; 46: 485-493 * Crossref * PubMed * Scopus (1) * Google Scholar There is a need for a more simplified CPR that offers better clinical translation. Using existing residual lower extremity motor function as a walking predictor works for those on either end of the SCI severity spectrum (ie, no motor recovery vs substantial motor recovery), 10 * Waters RL * Adkins RH * Yakura JS * Sie I Motor and sensory recovery following incomplete tetraplegia. Arch Phys Med Rehabil. 1994; 75: 306-311 * Abstract * Full Text PDF * PubMed * Scopus (197) * Google Scholar , 11 * Crozier KS * Cheng LL * Graziani V * Zorn G * Herbison G * Ditunno JF Spinal cord injury: prognosis for ambulation based on quadriceps recovery. Paraplegia. 1992; 30: 762-767 * Crossref * PubMed * Google Scholar but this is arguably a clinically-obvious prognosis. Indeed, motor-based CPRs do not work as well for those initially classified in the middle of the SCI severity spectrum where only minimal sensorimotor function is present. 12 * Phan P * Budhram B * Zhang Q * et al. Highlighting discrepancies in walking prediction accuracy for patients with traumatic spinal cord injury: an evaluation of validated prediction models using a Canadian Multicenter Spinal Cord Injury Registry. Spine J. 2019; 19: 703-710 * Abstract * Full Text * Full Text PDF * PubMed * Google Scholar There is need for a clinical tool to predict future independent walking ability after SCI that works for those in the middle of the SCI severity spectrum and does not rely on motor scores. The presence or absence of sensing pinprick below the level of SCI has demonstrated promise to serve as a predictor variable for future walking ability. 10 * Waters RL * Adkins RH * Yakura JS * Sie I Motor and sensory recovery following incomplete tetraplegia. Arch Phys Med Rehabil. 1994; 75: 306-311 * Abstract * Full Text PDF * PubMed * Scopus (197) * Google Scholar , 13 * Crozier KS * Graziani V * Ditunno JF * Herbison GJ Spinal cord injury: prognosis for ambulation based on sensory examination in patients who are initially motor complete. Arch Phys Med Rehabil. 1991; 72: 119-121 * PubMed * Google Scholar , 14 * v Oleson C * AS Burns * Ditunno JF * Geisler FH * Coleman WP Prognostic value of pinprick preservation in motor complete, sensory incomplete spinal cord injury. Arch Phys Med Rehabil. 2005; 86: 988-992 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (55) * Google Scholar , 15 * v Oleson C * RJ Marino * Leiby BE * Ditunno JF Influence of age alone, and age combined with pinprick, on recovery of walking function in motor complete, sensory incomplete spinal cord injury. Arch Phys Med Rehabil. 2016; 97: 1635-1641 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (19) * Google Scholar , 16 * Katoh S * el Masry WS Motor recovery of patients presenting with motor paralysis and sensory sparing following cervical spinal cord injuries. Paraplegia. 1995; 33: 506-509 * Crossref * PubMed * Google Scholar , 17 * Foo D * Subrahmanyan TS * Rossier AB Post-traumatic acute anterior spinal cord syndrome. Paraplegia. 1981; 19: 201-205 * Crossref * PubMed * Google Scholar Per the American Spinal Injury Association Impairment Scale (AIS), people classified with AIS B injuries (sensory sparing but motor complete) under 50 years old, having substantial pinprick sensation in the lower extremities was associated with an increased likelihood of household ambulation 1 year after SCI. 15 * v Oleson C * RJ Marino * Leiby BE * Ditunno JF Influence of age alone, and age combined with pinprick, on recovery of walking function in motor complete, sensory incomplete spinal cord injury. Arch Phys Med Rehabil. 2016; 97: 1635-1641 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (19) * Google Scholar Dermatomal testing of pinprick sensation is 1 part of the International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI) examination, 18 ASIA and ISCoS International Standards Committee The 2019 revision of the International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI)-What's new?. Spinal Cord. 2019; 57: 815-817 * Crossref * PubMed * Scopus (0) * Google Scholar which is the criterion standard SCI clinical exam. The full ISNCSCI exam may take longer than 45 minutes to complete 19 * Kirshblum S * Snider B * Rupp R * Read MS International Standards Committee of ASIA and ISCoS Updates of the International Standards for Neurologic Classification of Spinal Cord Injury: 2015 and 2019. Phys Med Rehabil Clin N Am. 2020; 31: 319-330 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (65) * Google Scholar and may not be feasible during the acute phase of SCI due to sedation or long bone fracture. Thus, a CPR using more targeted sensory information may be beneficial. Light touch sensation may be another variable to consider for the prediction of ambulation, as dermatomal testing of light touch is another part of the ISNCSCI exam and also does not rely on motor scores. 18 ASIA and ISCoS International Standards Committee The 2019 revision of the International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI)-What's new?. Spinal Cord. 2019; 57: 815-817 * Crossref * PubMed * Scopus (0) * Google Scholar Two established CPRs included S1 dermatome lower extremity light touch scores as predictor variables for future walking. 3 * van Middendorp JJ * Hosman AJ * Donders ART * et al. A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury: a longitudinal cohort study. Lancet. 2011; 377: 1004-1010 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (183) * Google Scholar , 4 * Hicks KE * Zhao Y * Fallah N * et al. A simplified clinical prediction rule for prognosticating independent walking after spinal cord injury: a prospective study from a Canadian multicenter spinal cord injury registry. Spine J. 2017; 17: 1383-1392 * Abstract * Full Text * Full Text PDF * PubMed * Google Scholar Questions remain as to what type of sensory testing may best predict independent walking after SCI. The objective of this study was to use a large, multisite SCI dataset to derive and independently validate a simple and accurate CPR to predict future independent walking ability after SCI at the bedside that does not rely on motor scores and is predictive for those initially classified in the middle of the SCI severity spectrum (AIS B and C injuries). METHODS This was a retrospective analysis of SCI Model Systems (SCIMS) data from 12 centers in the United States of America. This study was approved by the local Institutional Review Board and complies with the Declaration of Helsinki standards. INCLUSION CRITERIA To be included in the study, each participant's dataset required the following variables to be available for analysis: diagnosis of traumatic SCI; cervical, thoracic, or lumbar level of injury; lower extremity pinprick and light touch sensory scores within 31 days after SCI; walking outcomes at 1 year after SCI; and data available from the national SCIMS database from April 2004 to March 2021. OUTCOME MEASURE AND INDEPENDENT VARIABLES Similar to previous studies, 2 outcome variables collected 1 year after SCI with yes/no answers were selected from the SCIMS Data Dictionary for the National SCI Database Form II: “Are you able to walk (with or without mobility aid) for 150 feet in your home?” 20 * Smith AC * Albin SR * O'Dell DR * et al. Axial MRI biomarkers of spinal cord damage to predict future walking and motor function: a retrospective study. Spinal Cord. 2021; 59: 693-699 * Crossref * PubMed * Scopus (3) * Google Scholar and “Are you able to walk (with or without mobility aid) for one street block outside?” 6 * Draganich C * Weber KA * Thornton WA * et al. Predicting outdoor walking 1 year after spinal cord injury: a retrospective, multisite external validation study. J Neurol Phys Ther. 2023; 47: 155-161 * Crossref * PubMed * Scopus (0) * Google Scholar , 21 * Berliner JC * O'Dell DR * Albin SR * et al. The influence of conventional T2 MRI indices in predicting who will walk outside one year after spinal cord injury. J Spinal Cord Med. 2023; 46: 501-507 * Crossref * PubMed * Scopus (5) * Google Scholar Independent walking was defined based on a “yes” answer to both self-reported ability to walk indoors 150 feet and outdoors 1 street block. Bilateral lower extremity sharp/dull discrimination (pinprick) and light touch sensory scores from the L3 through S4-5 dermatomes from the ISNCSCI examination, collected at the time of rehabilitation admission (≤31 days from SCI), were used to predict walking. Those who were not independent walkers were defined by a lack of an answer “yes” to both walking outcome questions. Thus, the outcome being tested was a binary variable, either independent walkers or not. DERIVING AND VALIDATING THE CLINICAL PREDICTION RULE Binary variables were derived for pinprick and light touch sensory scores at each dermatome that indicated normal sensation bilaterally (both left and right), normal sensation unilaterally (left or right), any sensation (normal or altered) bilaterally (left and right), and any sensation unilaterally (left or right). Next, a SCIMS center that had a large sample size and balanced number of independent walkers and non-independent walkers was chosen to derive the CPR (derivation dataset). Statistical analyses were conducted using Python (version=3.7.11) Scikit-Learn (version=0.21.2), and Scipy (version=1.7.3) libraries for machine-learning and scientific computing. Positive and negative predictive values (PPV and NPV, respectively) are values that can be used to appraise the success of a clinical test for predicting whether a patient will truly have a desired outcome based on a positive or negative test result. 22 * Monaghan TF * Rahman SN * Agudelo CW * et al. Foundational statistical principles in medical research: sensitivity, specificity, positive predictive value, and negative predictive value. Medicina (Kaunas). 2021; 57: 503 * Crossref * PubMed * Scopus (30) * Google Scholar Using true and false positive counts along with true and false negative counts, the PPV assesses the probability of having the desired outcome based on a positive test result (ie, “yes” response to predictor variable), while NPV assesses the probability of not achieving the desired outcome based on a negative test result (ie, “no” response to predictor variable). 22 * Monaghan TF * Rahman SN * Agudelo CW * et al. Foundational statistical principles in medical research: sensitivity, specificity, positive predictive value, and negative predictive value. Medicina (Kaunas). 2021; 57: 503 * Crossref * PubMed * Scopus (30) * Google Scholar For this study, PPVs and NPVs were calculated across the full derivation dataset as well as the derivation subset including only those in the middle of the recovery spectrum (AIS B and C). Across 10,000 bootstrapped samples, 95% confidence intervals (CI) were calculated for each PPV and NPV of the binary variables. Considering both the whole derivation dataset along with a subset including only those in the middle of the recovery spectrum (AIS B and C), the single sensory modality and dermatome that first maximized the PPV (primary measure) and then the NPV (secondary measure) was identified. Pinprick and light touch predictor variables across all dermatomes (L3 through S4-5) were considered and assessed (see fig 1). The most optimal sensory modality (either pinprick or light touch) at the most optimal dermatome was selected to be used as the predictor variable. This single-sensory-modality-and-dermatome predictor variable was then used to derive the CPR (see fig 1), which was then validated on an independent dataset, using the patients from the other SCIMS centers (validation dataset). Attempting to boost predictive performance in the AIS B and C validation dataset subgroup, the CPR was applied to those under the age of 50 vs those 50 years and older. To investigate the possible influence of upper vs lower motor neuron injury, the derived CPR was also tested separately on participants within the validation dataset with only cervicothoracic neurologic level injuries (n=2826) and only lumbar neurologic level injuries (n=185). Finally, to study potential influence of the time of pinprick exam on predictive performance, we performed a sub-analysis on the validation dataset for 3 time windows of pinprick testing: within 0-3 days of SCI, within 4-7 days of SCI, or within 8-31 days of SCI. Fig 1Positive and negative predictive values of the candidate CPR variables derived from the pinprick (A) and light touch sensory scores (B) in the derivation dataset (n=623). For each dermatome and the pinprick and light touch sensory scores, we derived binary variables that indicated normal sensation bilaterally (both left and right), normal sensation unilaterally (left or right), any sensation (normal or altered) bilaterally (left and right), and any sensation (normal or altered) unilaterally (left or right). Mean PPVs and NPVs are shown for each candidate variable (●). Error bars=bootstrapped 95% CIs. ★=Used in CPR. * View Large Image * Figure Viewer * Download Hi-res image * Download (PPT) RESULTS The derivation dataset consisted of 623 participants, with 261 independent walkers and 362 non-walkers. See table 1 for a summary of both the derivation and validation datasets. Pinprick at the L4 and S1 dermatomes yielded the optimal PPV (primary measure, 89% and 89%, respectively) and NPV (secondary measure, 82% and 81%, respectively) for predicting independent walking in the whole derivation dataset (fig 1). When considering the AIS B and C subset of the derivation dataset, pinprick at the S1 dermatome yielded the optimal PPVs (primary measure, 69%) and NPVs (secondary measure, 68%) for predicting independent walking (fig 2). Therefore, pinprick sensation at S1 was used to derive the CPR. See table 2 for a breakdown of the CPR prediction statistics, including true and false positives, true and false negatives, accuracy, sensitivity, specificity, PPV, and NPV. Table 1Demographic information DatasetNAge (Years)% MenIndependent WalkersNon-Independent WalkersInitial AIS AInitial AIS BInitial AIS CInitial AIS DDerivation (Full)62342.8±18.0 (1)79.826136224861118196Derivation (AIS B&C)17943.7±17.4 (0)79.9791000611180Validation (Full)305642.8±17.9 (22)79.1119118651161398636861Validation (AIS B&C)103444.0±17.5 (7)78.437565903986360Validation (Cervicothoracic) * In the validation dataset, 45 participants had missing neurologic injury level data and were excluded from the cervicothoracic and lumbar neurologic injury level analysis. 282643.3±18.0 (21)79.0104517811090350587799Validation (Lumbar) * In the validation dataset, 45 participants had missing neurologic injury level data and were excluded from the cervicothoracic and lumbar neurologic injury level analysis. 18536.4±16.1 (1)81.11295648434648 NOTE. Age displayed as mean ± 1 standard deviation with (#) indicating number of participants with missing data. In the validation dataset, 45 participants had missing neurologic injury level data and were excluded from the cervicothoracic and lumbar neurologic injury level analysis. * Open table in a new tab Fig 2Positive and negative predictive values of the candidate CPR variables derived from the pinprick sensory scores at the L4 and S1 dermatomes in the AIS B and C derivation dataset subset (n=179). In the whole derivation dataset, pinprick at the L4 and S1 dermatomes had similar predictive value (fig 1). When considering the AIS B and C subset of the derivation dataset, pinprick at the S1 dermatome yielded the optimal PPV (primary measure) and NPV (secondary measure) for predicting independent walking, so pinprick sensation at S1 was used to derive the CPR. Mean PPVs and NPVs are shown for each candidate variable (●). Error bars=bootstrapped 95% CIs. ★=Used in CPR. * View Large Image * Figure Viewer * Download Hi-res image * Download (PPT) Table 2Clinical prediction rule prediction results DatasetNPredictorTrue NegativeFalse PositiveFalse NegativeTrue PositiveSensitivitySpecificityAccuracyPPVNPVDerivation (Full)623Normal left and right S1 pinprick sensation351111758632.9 (27.4, 38.8)97.0 (95.1, 98.6)70.1 (66.5, 73.7)88.7 (81.9, 94.6)66.7 (62.6,70.8)Derivation (Full)623Any S1 pinprick sensation left or right302606919273.6 (68.2,78.7)83.4 (79.5,87.1)79.3 (76.1,82.5)76.2 (70.7, 81.3)81.4 (77.3, 85.3)Derivation (AIS B and C)179Normal left and right S1 pinprick sensation96470911.3 (4.9, 18.8)96.0 (91.7, 99.1)58.7 (51.4,65.9)69.2 (41.7, 92.9)57.8 (50.3, 65.3)Derivation (AIS B and C)179Any S1 pinprick sensation left or right6931334658.2 (47.4,69.0)69.0 (59.8,77.9)64.3 (57.5,70.9)59.7 (48.7, 70.5)67.7 (58.5, 76.5)Validation (Full)3056Normal left and right S1 pinprick sensation18135287931226.2 (23.7,28.7)97.2 (96.4,97.9)69.5 (67.9,71.2)85.7 (82.0, 89.2)67.3 (65.6, 69.1)Validation (Full)3056Any S1 pinprick sensation left or right159527032386872.9 (70.3,75.4)85.5 (84,87.1)80.6 (79.2,82)76.3 (73.8, 78.8)83.2 (81.5, 84.8)Validation (AIS B and C)1034Normal left and right S1 pinprick sensation636233294612.3 (9.0,15.7)96.5 (95.0,97.9)66.0 (63.1,68.9)66.7 (55.4, 77.6)65.9 (62.9, 68.9)Validation (AIS B and C)1034Any S1 pinprick sensation left or right47918016021557.3 (52.2,62.3)72.7 (69.3,76.1)67.1 (64.2,70)54.4 (49.5, 59.3)75.0 (71.5, 78.3)Validation (AIS B and C under 50 years old)575Normal left and right S1 pinprick sensation34362012511.1 (7.2,15.2)98.3 (96.8,99.4)64.0 (60.0, 68.0)80.7 (65.6,93.8)63.1 (59.0,67.1)Validation (AIS B and C under 50 years old)575Any S1 pinprick sensation left or right271789613057.5 (50.9,64)77.7 (73.2,82.0)69.7 (65.9,73.4)62.5 (55.8,69.0)73.8 (69.2,78.3)Validation (AIS B and C, 50 years and older)452Normal left and right S1 pinprick sensation288171272013.6 (8.2,19.3)94.4 (91.7,96.9)68.1 (63.7,72.3)53.9 (37.5,70.3)69.4 (64.9,73.7)Validation (AIS B and C, 50 years and older)452Any S1 pinprick sensation left or right204101648356.4 (48.3,64.4)66.9 (61.5,72.2)63.5 (59.1,67.9)45.1 (37.8,52.4)76.1 (71.0.81.2)Validation (Cervicothoracic) * In the validation dataset, 45 participants had missing neurologic injury level data and were excluded from the cervicothoracic and lumbar neurologic injury level analysis. 2826Normal left and right S1 pinprick sensation17305176428126.9 (24.3,29.6)97.1 (96.3,97.9)71.2 (69.5,72.8)84.6 (80.6, 88.4)69.4 (67.6, 71.2)Validation (Cervicothoracic) * In the validation dataset, 45 participants had missing neurologic injury level data and were excluded from the cervicothoracic and lumbar neurologic injury level analysis. 2826Any S1 pinprick sensation left or right152725426677974.6 (71.9,77.1)85.7 (84.1,87.3)81.6 (80.2,83.0)75.4 (72.8, 77.9)85.2 (83.5, 86.8)Validation (Lumbar) * In the validation dataset, 45 participants had missing neurologic injury level data and were excluded from the cervicothoracic and lumbar neurologic injury level analysis. 185Normal left and right S1 pinprick sensation5511022720.9 (14.1,28.1)98.2 (94.1,100)44.3 (37.3,51.4)96.4 (88.0, 100.0)35.1 (27.7, 42.8)Validation (Lumbar) * In the validation dataset, 45 participants had missing neurologic injury level data and were excluded from the cervicothoracic and lumbar neurologic injury level analysis. 185Any S1 pinprick sensation left or right4115537658.9 (50.4,67.4)73.1 (61.0,84.4)63.2 (56.2,70.3)83.4 (75.5, 90.7)43.6 (33.7, 53.8) NOTE. Data for Sensitivity, Specificity, Accuracy, PPV, and NPV are displayed as mean (95% confidence intervals). In the validation dataset, 45 participants had missing neurologic injury level data and were excluded from the cervicothoracic and lumbar neurologic injury level analysis. * Open table in a new tab In the whole derivation dataset, normal pinprick sensation bilaterally at S1 had a PPV of 89% (95% CI=82%-95%) for independent walking. Any pinprick sensation unilaterally at S1 had a PPV of 76% (95% CI=71%-81%) for independent walking. Any pinprick sensation unilaterally at S1 had an NPV of 81% (95% CI=77%-85%) for independent walking. In the AIS B and C derivation subset (n=179, AIS B=61, AIS C=118), normal pinprick sensation bilaterally at S1 had a PPV of 69% (95% CI=42%-93%), any pinprick sensation unilaterally at S1 had a PPV of 60% (95% CI=49%-71%) and any pinprick sensation unilaterally at S1 had an NPV of 68% (95% CI=59%-77%). Two variables, normal pinprick sensation unilaterally at S1 and any pinprick sensation bilaterally at S1, provided inferior PPVs and NPVs in comparison with normal pinprick sensation bilaterally at S1 and any pinprick sensation unilaterally at S1. Therefore, these 2 variables (normal pinprick sensation unilaterally at S1 and any pinprick sensation bilaterally at S1) were not considered for the CPR. The validation dataset consisted of 3056 participants, with 1191 independent walkers and 1865 non-walkers. In the whole validation dataset, normal pinprick sensation bilaterally at S1 had a PPV of 86% (95% CI=82%-89%) for independent walking. Any pinprick sensation unilaterally at S1 had a PPV of 76% (95% CI=74%-79%) for independent walking. Any pinprick sensation unilaterally at S1 had an NPV of 83% (95% CI=82%-85%) for independent walking. In the AIS B and C validation subset (N=1034; AIS B=398, AIS C=636), normal pinprick sensation bilaterally at S1 had a PPV of 67% (95% CI=55%-78%). Any pinprick sensation unilaterally at S1 had a PPV of 54% (95% CI=50%-59%). Any pinprick sensation unilaterally at S1 had an NPV of 75% (95% CI=72%-78%). In the AIS B and C validation subset of those age less than 50 (N=575), normal pinprick sensation bilaterally at S1 had a PPV of 81% (95% CI=66%-94%). Any pinprick sensation unilaterally at S1 had a PPV of 63% (95% CI=56%-69%). Any pinprick sensation unilaterally at S1 had an NPV of 74% (95% CI=69%-78%). In the AIS B and C validation subset of those age 50 years and older (N=452), normal pinprick sensation bilaterally at S1 had a PPV of 54% (95% CI=38%-70%). Any pinprick sensation unilaterally at S1 had a PPV of 45% (95% CI=38%-52%). Any pinprick sensation unilaterally at S1 had an NPV of 76% (95% CI=71%-81%). In the validation dataset, 45 participants had missing neurologic injury level data and were excluded from the cervicothoracic and lumbar neurologic injury level analysis. In the lumbar SCI validation subset (N=185), normal pinprick sensation bilaterally at S1 had a PPV of 96% (95% CI=88%-100%). Any pinprick sensation unilaterally at S1 had a PPV of 83% (95% CI=76%-91%). Any pinprick sensation unilaterally at S1 had an NPV of 44% (95% CI=34%-54%). In the cervicothoracic SCI validation subset (N=2826), normal pinprick sensation bilaterally at S1 had a PPV of 85% (95% CI=81%-88%). Any pinprick sensation unilaterally at S1 had a PPV of 75% (95% CI=73%-78%). Any pinprick sensation unilaterally at S1 had an NPV of 85% (95% CI=84%-87%). See table 2 for a breakdown of the CPR prediction statistics for the lumbar SCI and cervicothoracic SCI validation subsets. In the validation subset of those who received pinprick testing within 0-3 days of SCI (N = 49), normal pinprick sensation bilaterally at S1 had a PPV of 87% (95% CI=67%-100%). Any pinprick sensation unilaterally at S1 had a PPV of 93% (95% CI=81%-100%). Any pinprick sensation unilaterally at S1 had an NPV of 59% (95% CI=38%-79%). In the validation subset of those who received pinprick testing within 4-7 days of SCI (N=599), normal pinprick sensation bilaterally at S1 had a PPV of 93% (95% CI=88%-97%). Any pinprick sensation unilaterally at S1 had a PPV of 87% (95% CI=83%-91%). Any pinprick sensation unilaterally at S1 had an NPV of 72% (95% CI=67%-77%). In the validation subset of those who received pinprick testing within 8-31 days of SCI (N=2408), normal pinprick sensation bilaterally at S1 had a PPV of 82% (95% CI=77%-87%). Any pinprick sensation unilaterally at S1 had a PPV of 72% (95% CI=69%-75%). Any pinprick sensation unilaterally at S1 had an NPV of 86% (95% CI=84%-87%). See table 3 for a breakdown of the CPR prediction statistics by time window of pinprick testing. See figure 3 depicting the CPR. Table 3Clinical prediction rule results by time window of pinprick test DatasetNPredictorTrue NegativeFalse PositiveFalse NegativeTrue PositiveSensitivitySpecificityAccuracyPPVNPVValidation: pinprick assessed within 0-3 days of SCI49Normal left and right S1 pinprick sensation132211338.2 (22.2, 54.5)86.7 (68.4, 100)53.1 (38.8, 67.3)86.7 (66.7, 100)38.2 (22.2, 55)Validation: pinprick assessed within 0-3 days of SCI49Any S1 pinprick sensation left or right13292573.5 (57.9, 87.9)86.7 (68.4, 100)77.6 (65.3, 87.8)92.6 (81.0, 100)59.1 (38.1, 79.2)Validation: pinprick assessed within 4-7 days of SCI599Normal left and right S1 pinprick sensation249823710530.7 (25.9, 35.7)96.9 (94.6, 98.8)59.1 (55.1, 62.9)92.9 (87.9, 97.3)51.2 (46.7, 55.6)Validation: pinprick assessed within 4-7 days of SCI599Any S1 pinprick sensation left or right219388525775.1 (70.5, 79.7)85.2 (80.8, 89.5)79.5 (76.3, 82.6)87.1 (83.2, 90.9)72.0 (67.0, 77.0)Validation: pinprick assessed within 8-31 days of SCI2408Normal left and right S1 pinprick sensation15514262119423.8 (20.9, 26.7)97.4 (96.5, 98.1)72.5 (70.7, 74.3)82.2 (77.1, 87)71.4 (69.6, 73.3)Validation: pinprick assessed within 8-31 days of SCI2408Any S1 pinprick sensation left or right136323022958671.9 (68.9, 75.0)85.6 (83.8, 87.3)80.9 (79.4, 82.5)71.8 (68.7, 74.9)85.6 (83.9, 87.3) NOTE. Data for sensitivity, specificity, accuracy, PPV, and NPV are displayed as mean (95% CI). * Open table in a new tab Fig 3The S1 lateral heel pinprick clinical prediction rule. * View Large Image * Figure Viewer * Download Hi-res image * Download (PPT) DISCUSSION In this large multi-site retrospective study, we derived and validated a CPR using only pinprick sensory testing at the lateral heels (ie, S1 dermatomes) within 31 days of SCI to accurately identify future independent walkers 1 year after SCI. For our full validation dataset, ≈9 of 10 people with SCI and normal pinprick sensation at both the left and right lateral heels endorsed independent walking, and ≈8 of 10 people with any pinprick at either the left or right lateral heels endorsed independent walking. In contrast, ≈8 of 10 people without any pinprick sensation unilaterally (ie, no pinprick sensation at either the left or right lateral heel) did not endorse independent walking. Importantly, for people initially classified within the middle of the SCI severity spectrum (ie, AIS B and C classification), who present the greatest challenge when predicting clinical trajectory, ≈7 of 10 with normal pinprick sensation at both the left and right lateral heels endorsed independent walking, while ≈8 of 10 people with no pinprick sensation at either the left or right lateral heel did not endorse independent walking. 12 * Phan P * Budhram B * Zhang Q * et al. Highlighting discrepancies in walking prediction accuracy for patients with traumatic spinal cord injury: an evaluation of validated prediction models using a Canadian Multicenter Spinal Cord Injury Registry. Spine J. 2019; 19: 703-710 * Abstract * Full Text * Full Text PDF * PubMed * Google Scholar This CPR provides clinicians with a tool that has predictive value for people across the recovery spectrum including those with AIS B and C injuries. Overall, we demonstrate that pinprick sensory testing at the S1 dermatome(s) can be used to accurately predict high level walking ability 1 year after SCI (both indoors and outdoors). Limiting the CPR to only the S1 dermatome provides a simple and accurate tool for predicting independent walking 1 year after SCI. Furthermore, the variable for this CPR can easily be obtained by assessing pinprick sensation at the lateral heels at bedside. Our results are in alignment with previous studies that found pinprick sensation to be important in the prediction of future functional recovery. Waters et al found that 16% of people with motor complete SCI who had bilateral sacral pinprick sensation eventually regained some voluntary movement in the lower extremities. 10 * Waters RL * Adkins RH * Yakura JS * Sie I Motor and sensory recovery following incomplete tetraplegia. Arch Phys Med Rehabil. 1994; 75: 306-311 * Abstract * Full Text PDF * PubMed * Scopus (197) * Google Scholar In another study by Crozier et al in 27 people with initial motor complete SCI, 89% of those with pinprick sensation below the zone of injury recovered walking ability of at least 200 feet. 13 * Crozier KS * Graziani V * Ditunno JF * Herbison GJ Spinal cord injury: prognosis for ambulation based on sensory examination in patients who are initially motor complete. Arch Phys Med Rehabil. 1991; 72: 119-121 * PubMed * Google Scholar In a more recent study of 131 people with initial motor complete SCI, Oleson et al found that walking ability was significantly better 1 year post injury for a subgroup of people with pinprick preserved in at least 50% of lower extremity dermatomes (L2 through S1). 14 * v Oleson C * AS Burns * Ditunno JF * Geisler FH * Coleman WP Prognostic value of pinprick preservation in motor complete, sensory incomplete spinal cord injury. Arch Phys Med Rehabil. 2005; 86: 988-992 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (55) * Google Scholar We believe that our CPR is straightforward to implement at the bedside. After SCI, if the individual can perceive pinprick sensation at the right and left lateral heels and it feels normal, then there is a good prognosis for recovering future independent walking ability. If the individual reports any pinprick sensation in either lateral heel, even if it feels different than other unimpaired skin areas (ie, face), then there is a fair prognosis for recovering future independent walking ability. If the individual cannot feel pinprick sensation at either lateral heel, then there is a poor prognosis for recovering future independent walking ability. For these fair and poor prognosis cases, wheelchair training and compensatory strategies may be prioritized, 23 * Morgan KA * Engsberg JR * Gray DB Important wheelchair skills for new manual wheelchair users: health care professional and wheelchair user perspectives. Disabil Rehabil Assist Technol. 2017; 12: 28-38 * Crossref * PubMed * Scopus (17) * Google Scholar , 24 * Rigot S * Worobey L * Boninger ML Gait training in acute spinal cord injury rehabilitation-utilization and outcomes among nonambulatory individuals: findings from the SCIRehab Project. Arch Phys Med Rehabil. 2018; 99: 1591-1598 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (3) * Google Scholar and additional neuromodulation may be necessary to achieve improved voluntary mobility and/or walking. 25 * Tefertiller C * Rozwod M * VandeGriend E * Bartelt P * Sevigny M * Smith AC Transcutaneous electrical spinal cord stimulation to promote recovery in chronic spinal cord injury. Front Rehabil Sci. 2021; 2740307 * PubMed * Google Scholar , 26 * Smith A * Angeli C * Ugiliweneza B * et al. Spinal cord imaging markers and recovery of standing with epidural stimulation in individuals with clinically motor complete spinal cord injury. Exp Brain Res. 2022; 240: 279-288 * Crossref * PubMed * Scopus (5) * Google Scholar , 27 * Rowald A * Komi S * Demesmaeker R * et al. Activity-dependent spinal cord neuromodulation rapidly restores trunk and leg motor functions after complete paralysis. Nat Med. 2022; 28: 260-271 * Crossref * PubMed * Scopus (86) * Google Scholar , 28 * Angeli CA * Boakye M * Morton RA * et al. Recovery of over-ground walking after chronic motor complete spinal cord injury. N Engl J Med. 2018; 379: 1244-1250 * Crossref * PubMed * Scopus (331) * Google Scholar , 29 * Gill ML * Grahn PJ * Calvert JS * et al. Neuromodulation of lumbosacral spinal networks enables independent stepping after complete paraplegia. Nat Med. 2018; 24: 1677-1682 * Crossref * PubMed * Scopus (308) * Google Scholar Regarding an optimal time window of pinprick exam to optimize predictive performance, we found that the earlier time windows (within 0-3 days and 4-7 days of SCI) provided better PPV than the later time window (within 8-31 days of SCI). However, the later time window provided better NPV. These data suggest that our CPR may work best for ruling in future independent walkers when applied within 0-7 days of SCI, yet may work best for ruling out future independent walkers when applied later on. The underlying reasons for the importance of pinprick sensation regarding future motor recovery may be rooted in the anatomic locations of the human spinal cord's ascending and descending tracts. The lateral corticospinal tracts, responsible for volitional motor output, are in close proximity to the lateral spinothalamic tracts which convey sharp pinprick sensation. 13 * Crozier KS * Graziani V * Ditunno JF * Herbison GJ Spinal cord injury: prognosis for ambulation based on sensory examination in patients who are initially motor complete. Arch Phys Med Rehabil. 1991; 72: 119-121 * PubMed * Google Scholar , 30 * Smith AC * Weber KA * O'Dell DR * Parrish TB * Wasielewski M * Elliott JM Lateral corticospinal tract damage correlates with motor output in incomplete spinal cord injury. Arch Phys Med Rehabil. 2018; 99: 660-666 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (16) * Google Scholar , 31 * Smith AC * O'Dell DR * Albin SR * et al. Lateral corticospinal tract and dorsal column damage: predictive relationships with motor and sensory scores at discharge from acute rehabilitation after spinal cord injury. Arch Phys Med Rehabil. 2022; 103: 62-68 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (0) * Google Scholar The main tracts that convey light touch sensation lie in the dorsal columns, which are farther away from the motor pathways. 31 * Smith AC * O'Dell DR * Albin SR * et al. Lateral corticospinal tract and dorsal column damage: predictive relationships with motor and sensory scores at discharge from acute rehabilitation after spinal cord injury. Arch Phys Med Rehabil. 2022; 103: 62-68 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (0) * Google Scholar Co-localization of the corticospinal and spinothalamic tracts may explain the relation between residual pinprick sensation and independent walking—pinprick sensation may act as a surrogate marker of corticospinal tract integrity. In alignment with our findings, several past CPRs identified sensory function at the S1 dermatome as an important predictor for future walking. 3 * van Middendorp JJ * Hosman AJ * Donders ART * et al. A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury: a longitudinal cohort study. Lancet. 2011; 377: 1004-1010 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (183) * Google Scholar , 4 * Hicks KE * Zhao Y * Fallah N * et al. A simplified clinical prediction rule for prognosticating independent walking after spinal cord injury: a prospective study from a Canadian multicenter spinal cord injury registry. Spine J. 2017; 17: 1383-1392 * Abstract * Full Text * Full Text PDF * PubMed * Google Scholar , 5 * Jean S * Mac-Thiong JM * Jean MC * Dionne A * Bégin J * Richard-Denis A Early clinical prediction of independent outdoor functional walking capacity in a prospective cohort of traumatic spinal cord injury patients. Am J Phys Med Rehabil. 2021; 100: 1034-1041 * Crossref * PubMed * Scopus (1) * Google Scholar , 6 * Draganich C * Weber KA * Thornton WA * et al. Predicting outdoor walking 1 year after spinal cord injury: a retrospective, multisite external validation study. J Neurol Phys Ther. 2023; 47: 155-161 * Crossref * PubMed * Scopus (0) * Google Scholar From a clinical perspective, S1 is a distal spinal cord segment that provides innervation to the lower extremity extensor muscle groups necessary for forward propulsion during walking. On the other hand, for our CPR, S1 pinprick sensation may be serving as a more global measure for spared sensation across the sacral segments and especially the most caudally innervated at S4-5. 32 * Zariffa J * Kramer JLK * Jones LAT * et al. Sacral sparing in SCI: beyond the S4-S5 and anorectal examination. Spine J. 2012; 12: 389-400 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (21) * Google Scholar In their 2020 study, Engel-Haber et al found improved CPR accuracy when using an age cut-off of 50 years old. 33 * Engel-Haber E * Zeilig G * Haber S * Worobey L * Kirshblum S The effect of age and injury severity on clinical prediction rules for ambulation among individuals with spinal cord injury. Spine J. 2020; 20: 1666-1675 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (5) * Google Scholar In alignment with these findings, when considering our AIS B and C validation subset with age less than 50, we found that, while other predictive metrics were not substantially improved, the PPV of having normal S1 bilateral pinprick sensation improved from 67% to 81%. This suggests that our CPR may work even better at ruling in future independent walkers if they are in the middle of the SCI severity spectrum and younger than 50 years old. When applying our CPR to the cervicothoracic SCI and lumbar SCI validation subsets, the PPVs for normal bilateral pinprick sensation (85% and 96%, respectively) and any pinprick sensation remained high (75% and 83%, respectively). However, the NPV for no pinprick sensation in either the left and right lateral heels was markedly lower for the lumbar SCI validation subset: only 44% in comparison with 85% in the cervicothoracic SCI validation subset. While we are unsure of the exact reasons underlying this finding, we hypothesize that some of these participants with lumbar SCIs may be classified with lower motor neuron injuries where function in key lower extremity muscles (ie, quadriceps) may have remained at least partially intact. These individuals may be able to walk independently using ankle-foot orthoses and/or other assistive devices. Taken together, these data suggest a good prognosis for those with lumbar neurologic level SCIs who have normal bilateral pinprick at the lateral heels, but our CPR does not rule out future independent walking if pinprick at the lateral heels is limited in this subgroup. STUDY LIMITATIONS Our intention was to create a simple CPR for those in the middle of the SCI severity spectrum but admittedly, our CPR is less accurate in the AIS B and C subgroup than the established van Middendorp and Hicks CPRs. 3 * van Middendorp JJ * Hosman AJ * Donders ART * et al. A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury: a longitudinal cohort study. Lancet. 2011; 377: 1004-1010 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (183) * Google Scholar , 4 * Hicks KE * Zhao Y * Fallah N * et al. A simplified clinical prediction rule for prognosticating independent walking after spinal cord injury: a prospective study from a Canadian multicenter spinal cord injury registry. Spine J. 2017; 17: 1383-1392 * Abstract * Full Text * Full Text PDF * PubMed * Google Scholar For their CPRs, overall accuracy is ≈74%, 12 * Phan P * Budhram B * Zhang Q * et al. Highlighting discrepancies in walking prediction accuracy for patients with traumatic spinal cord injury: an evaluation of validated prediction models using a Canadian Multicenter Spinal Cord Injury Registry. Spine J. 2019; 19: 703-710 * Abstract * Full Text * Full Text PDF * PubMed * Google Scholar vs our overall accuracy of 67% for our AIS B and C validation subgroup. When considering which CPR to use, simplicity and ease of clinical application without reliance on motor scores should be considered for our CPR, but this comes as a trade-off of reduced accuracy compared with the van Middendorp and Hicks CPRs. Next, the use of self-reported outcome measures for the walking outcome may not reflect actual walking performance, although past research found good accuracy with self-reporting in a cohort of individuals with SCI compared with physiatrist criterion standard. 34 * Harvey LA * Weber G * Heriseanu R * Bowden JL The diagnostic accuracy of self-report for determining S4-5 sensory and motor function in people with spinal cord injury. Spinal Cord. 2012; 50: 119-122 * Crossref * PubMed * Scopus (9) * Google Scholar STRENGTHS We believe that a major strength of our CPR lies in its simplicity. Our CPR only requires pinprick information at the right and left lateral heels (ie, S1 dermatomes) to predict walking 1 year after SCI. The lack of reliance on motor scores is a strength of our CPR. Another strength is our definition of independent walking, where each person had to endorse the ability to both walk indoors as well as outdoors at least 1 street block. A third strength of our study is the use of a multi-site dataset (12 sites) with a large and geographically diverse sample. The large sample size allowed us to independently derive (N=623) and validate (N=3056) the CPR, and the diversity in the sample likely improves the generalizability of the CPR to the United States SCI population. 35 * Ketchum JM * Cuthbert JP * Deutsch A * et al. Representativeness of the Spinal Cord Injury Model Systems National Database. Spinal Cord. 2018; 56: 126-132 * Crossref * PubMed * Scopus (11) * Google Scholar FUTURE DIRECTIONS A remaining research question is how to further improve the predictive value for the AIS B and C subpopulation. Adding other clinical variables, such as MRI-based measures of SCI, 20 * Smith AC * Albin SR * O'Dell DR * et al. Axial MRI biomarkers of spinal cord damage to predict future walking and motor function: a retrospective study. Spinal Cord. 2021; 59: 693-699 * Crossref * PubMed * Scopus (3) * Google Scholar , 21 * Berliner JC * O'Dell DR * Albin SR * et al. The influence of conventional T2 MRI indices in predicting who will walk outside one year after spinal cord injury. J Spinal Cord Med. 2023; 46: 501-507 * Crossref * PubMed * Scopus (5) * Google Scholar , 31 * Smith AC * O'Dell DR * Albin SR * et al. Lateral corticospinal tract and dorsal column damage: predictive relationships with motor and sensory scores at discharge from acute rehabilitation after spinal cord injury. Arch Phys Med Rehabil. 2022; 103: 62-68 * Abstract * Full Text * Full Text PDF * PubMed * Scopus (0) * Google Scholar , 36 * Smith AC * O'Dell DR * Thornton WA * et al. Spinal cord tissue bridges validation study: predictive relationships with sensory scores following cervical spinal cord injury. Top Spinal Cord Inj Rehabil. 2022; 28: 111-115 * Crossref * PubMed * Scopus (1) * Google Scholar might bolster the prediction of walking in this subgroup. Also, future research should consider external validation of our CPR in other cohorts and/or outside the United States. CONCLUSIONS In this large, multi-site retrospective study, we derived and validated a simple and accurate CPR that predicts future independent walking ability after SCI that does not rely on motor scores and works for those in the middle of the recovery spectrum. With pinprick sensory testing in a single dermatome, S1 at the lateral heels, clinicians can use our CPR to predict—within 31 days after SCI—who is likely to recover independent walking 1 year after traumatic SCI. REFERENCES 1. * Ditunno PL * Patrick M * Stineman M * Ditunno JF Who wants to walk? Preferences for recovery after SCI: a longitudinal and cross-sectional study. 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Spinal cord tissue bridges validation study: predictive relationships with sensory scores following cervical spinal cord injury. Top Spinal Cord Inj Rehabil. 2022; 28: 111-115 View in Article * Scopus (1) * PubMed * Crossref * Google Scholar ARTICLE INFO PUBLICATION HISTORY Published online: July 04, 2023 Accepted: June 22, 2023 Received in revised form: April 24, 2023 Received: January 24, 2023 PUBLICATION STAGE In Press Journal Pre-Proof FOOTNOTES This work was supported by the Craig Hospital Foundation. A.C.S. was supported by Eunice Kennedy Shriver National Institute of Child Health and Human Development of the National Institutes of Health—K01HD106928. Disclosures: A.C.S. and W.A.T. were supported by the Boettcher Foundation's Webb-Waring Biomedical Research Program. K.A.W. was supported by NIH National Institute of Neurological Disorders and Stroke of the National Institutes of Health—K23NS104211 and L30NS108301. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. IDENTIFICATION DOI: https://doi.org/10.1016/j.apmr.2023.06.015 COPYRIGHT © 2023 by the American Congress of Rehabilitation Medicine. Published by Elsevier Inc. USER LICENSE Creative Commons Attribution – NonCommercial – NoDerivs (CC BY-NC-ND 4.0) | How you can reuse Creative Commons Attribution – NonCommercial – NoDerivs (CC BY-NC-ND 4.0) PERMITTED FOR NON-COMMERCIAL PURPOSES: * Read, print & download * Redistribute or republish the final article * Text & data mine * Translate the article (private use only, not for distribution) * Reuse portions or extracts from the article in other works NOT PERMITTED * Sell or re-use for commercial purposes * Distribute translations or adaptations of the article Elsevier's open access license policy SCIENCEDIRECT Access this article on ScienceDirect A Single Dermatome Clinical Prediction Rule for Independent Walking 1 Year After Spinal Cord Injury * * * Hide CaptionDownloadSee figure in article Toggle Thumbstrip * Fig. 1 * Fig. 2 * Fig. 3 * View Large Image * Download Hi-res image * Download .PPT FIGURES * Fig 1Positive and negative predictive values of the candidate CPR variables derived from the pinprick (A) and light touch sensory scores (B) in the derivation dataset (n=623). For each dermatome and the pinprick and light touch sensory scores, we derived binary variables that indicated normal sensation bilaterally (both left and right), normal sensation unilaterally (left or right), any sensation (normal or altered) bilaterally (left and right), and any sensation (normal or altered) unilaterally (left or right). Mean PPVs and NPVs are shown for each candidate variable (●). Error bars=bootstrapped 95% CIs. ★=Used in CPR. * Fig 2Positive and negative predictive values of the candidate CPR variables derived from the pinprick sensory scores at the L4 and S1 dermatomes in the AIS B and C derivation dataset subset (n=179). In the whole derivation dataset, pinprick at the L4 and S1 dermatomes had similar predictive value (fig 1). When considering the AIS B and C subset of the derivation dataset, pinprick at the S1 dermatome yielded the optimal PPV (primary measure) and NPV (secondary measure) for predicting independent walking, so pinprick sensation at S1 was used to derive the CPR. Mean PPVs and NPVs are shown for each candidate variable (●). Error bars=bootstrapped 95% CIs. ★=Used in CPR. * Fig 3The S1 lateral heel pinprick clinical prediction rule. TABLES * Table 1Demographic information * Table 2Clinical prediction rule prediction results * Table 3Clinical prediction rule results by time window of pinprick test RELATED ARTICLES Hide CaptionDownloadSee figure in Article Toggle Thumbstrip * Download Hi-res image * Download .PPT * Home * Articles and Issues * Articles in Press * Conference Abstracts * Current Issue * Information/Education Pages * Measurement Tools * List of Issues * Podcasts * Supplements * Articles by Topic * From the Editors' Desk * Information/Education Pages * Journal-Based CME Article * Measurement of Environmental Barriers and Facilitators * Measurement Tools * For Authors * Author Information * Author Services * Permission to Reuse * Reporting Guidelines - Equator Network * Researcher Academy * Submit Your Manuscript * Journal Info * About the Journal * Activate Online Access * Contact Information * Editorial Board * Editorial Board Disclosures * ADVERTISING INFO * Pricing * Reprints * New Content Alerts * Supplement Policy * Subscribe * ACRM * ACRM Website * ACRM Members' Journal Access * Mission * Join ACRM * Latest News * Events * More Periodicals * Find a Periodical * Go to Product Catalog * Login & Register * Login * Register as a Guest * Register and Activate Your Subscription * Follow Us * Wikipedia * Linkedin * Twitter * Facebook -------------------------------------------------------------------------------- The content on this site is intended for healthcare professionals. -------------------------------------------------------------------------------- We use cookies to help provide and enhance our service and tailor content. 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