Smith's Fracture

A Smith's fracture (also called a "reverse Colles' fracture") is a transverse fracture of the distal radius with volar (palmar) displacement of the distal fragment — the opposite direction of the far more common Colles' fracture.[1] These fractures are inherently unstable due to the deforming forces of the wrist flexors and often require orthopedic consultation for definitive management.[2]

1. History

Mechanism of injury: Most commonly a fall onto the palm of the hand (61% of cases), a direct strike to the dorsum of the wrist, or falling over bicycle handlebars[3]
Finite element modeling shows Smith's fractures occur when the forearm-to-ground angle is 30°–45° in the sagittal plane and 75°–90° in the coronal plane[3]
Ask about hand dominance, occupation, functional demands, and activity level
Timing of injury, prior wrist injuries, and ability to move fingers/wrist post-injury
Numbness or tingling in the median nerve distribution (thumb, index, middle finger)
Anticoagulant use, osteoporosis history

2. Alarm Features

Acute carpal tunnel syndrome: Progressively worsening pain and paresthesias in the median nerve distribution — this is a surgical emergency requiring decompression[4]
Compartment syndrome: Pain out of proportion, pain with passive stretch of forearm muscles, tense forearm, paresthesias — irreversible damage can occur within 6 hours. Distal radius fractures with >35% translation or concurrent ipsilateral elbow injury carry particular risk[5-6]
Open fracture (skin puncture over fracture site)
Vascular compromise: absent radial pulse, cool/pale digits
Associated radiocarpal dislocation (Barton's variant) — requires significant force and suggests high-energy mechanism[1]

3. Medications

Acute analgesia: Acetaminophen, NSAIDs (ibuprofen 400–600 mg, naproxen 500 mg), opioids for severe pain
Hematoma block: 5–10 mL of 1% lidocaine injected into the fracture hematoma for reduction
Post-reduction/post-operative: Multimodal approach — scheduled acetaminophen + NSAID, limited opioid prescription (e.g., 20 tabs oxycodone 5 mg PRN)[7]
Avoid prolonged immobilization in palmar flexion (Cotton-Loder position) — this can precipitate median nerve neuropathy[4]
Consider calcium/vitamin D supplementation and osteoporosis workup in fragility fractures

4. Diet

Adequate calcium (1,000–1,200 mg/day) and vitamin D intake for bone healing
Protein-rich diet to support fracture recovery
Hydration to support tissue healing and reduce swelling

5. Review of Systems

Neurologic: Numbness/tingling in thumb, index, middle finger (median nerve); weakness of thumb opposition
Vascular: Finger color changes, temperature, capillary refill
Musculoskeletal: Ipsilateral elbow pain (rule out concurrent injury), shoulder pain, other extremity injuries
Constitutional: Mechanism suggestive of syncope, seizure, or other medical cause of fall
Endocrine: History of osteoporosis, menopause, thyroid disease

6. Collateral History and Family History

Witnesses to the fall — mechanism clarification
In elderly patients: assess for syncope, mechanical fall vs. medical cause
Family history of osteoporosis or fragility fractures
Social context: living situation, ability to perform ADLs with one functional hand, fall risk assessment

7. Risk Factors

Osteoporosis — lower bone mineral density correlates with more severe fracture patterns[8]
Female sex (21 of 26 patients in one series were female)[3]
Elderly age with fall risk
Cycling (falling over handlebars is a classic mechanism)[1]
High-energy trauma in younger patients (motor vehicle accidents, sports)
Prior distal radius fracture

8. Differential Diagnosis

Colles' fracture: Dorsal displacement (silver fork deformity) — opposite direction from Smith's[1]
Barton's fracture: Distal radius fracture with radiocarpal dislocation/subluxation (volar or dorsal); a Smith's fracture with dislocation is essentially a volar Barton's[1][9]
Chauffeur's (Hutchinson) fracture: Radial styloid fracture, intra-articular[1]
Scaphoid fracture: Anatomic snuffbox tenderness, often occult on initial radiographs
Distal radioulnar joint (DRUJ) injury: Isolated ligamentous injury without fracture
Galeazzi fracture: Radial shaft fracture with DRUJ dislocation[1]

9. Past Medical History

Prior wrist fractures or injuries
Osteoporosis or osteopenia (DEXA results)
Rheumatoid arthritis or other inflammatory arthropathy
Carpal tunnel syndrome (pre-existing median neuropathy)
Diabetes (affects healing and neuropathy assessment)
Anticoagulation therapy

10. Physical Exam

Inspection: Volar displacement of the distal fragment produces a "garden spade" deformity (opposite of the dorsal "dinner fork" deformity of Colles')
Palpation: Tenderness over the distal radius, assess for DRUJ tenderness and ulnar styloid tenderness
Neurovascular exam: Mandatory — assess median nerve function (sensation to thumb/index/middle finger, thumb opposition), radial and ulnar pulses, capillary refill
Wrist edema, deformity, and pain with pronation are strong predictors of fracture (combined sensitivity 94%)[1][10]
Ecchymosis is the most specific finding for fracture (97.8%)[10]
Assess for skin integrity (open fracture), forearm compartment tension
Examine ipsilateral elbow and shoulder

11. Lab Studies

Labs are generally not required for isolated Smith's fractures
In elderly/fragility fractures: consider CBC, BMP, calcium, vitamin D, TSH, and DEXA scan as outpatient
If surgical intervention planned: CBC, BMP, coagulation studies, type and screen per institutional protocol
In high-energy trauma: standard trauma labs as indicated

12. Imaging

First-line: PA and lateral wrist radiographs — essential to evaluate displacement direction, angulation, and articular involvement[1][11]
The lateral view is critical for identifying volar angulation/displacement that defines a Smith's fracture
Assess radiographic parameters: radial shortening, volar tilt, intra-articular step-off, DRUJ alignment
CT scan: Consider for intra-articular fractures to better characterize articular involvement and guide surgical planning[12]
Post-reduction radiographs are mandatory to confirm acceptable alignment
Imaging is unnecessary only if clinical exam reliably excludes fracture (rare in this context)

13. Special Tests

Thomas Classification (specific to Smith's fractures)

Type I: Extra-articular transverse fracture with volar displacement (most classic)
Type II: Oblique fracture line from dorsal lip to volar cortex with volar displacement of the distal fragment along with the carpus (essentially a volar Barton's fracture)
Type III: Extra-articular fracture with volar displacement and intra-articular extension into the radiocarpal joint
AAOS/ASSH surgical indications (for distal radius fractures in patients <65 years):[14-15]
Post-reduction radial shortening >3 mm
Dorsal tilt >10°
Intra-articular displacement or step-off >2 mm
Point-of-care ultrasound (POCUS) can be used as an adjunct for fracture identification in some settings.[1]

14. ECG

Not routinely indicated for isolated Smith's fracture
Consider ECG if the fall may have been caused by syncope, arrhythmia, or other cardiac etiology — particularly in elderly patients
Obtain ECG if procedural sedation is planned for reduction

15. Assessment

Smith's fracture is an inherently unstable distal radius fracture pattern due to the volar displacement and the deforming pull of the wrist flexors. Unlike Colles' fractures, Smith's fractures are more difficult to maintain in reduction with casting alone, and many ultimately require operative fixation.[2] The Thomas classification helps guide management: Type I and II fractures tend to have moderate results with conservative management, while Type III (extra-articular) may be more amenable to non-operative treatment.[2]

Key complications include

Median nerve injury — the most common early neurologic complication of distal radius fractures[4][16]
Malunion with persistent volar angulation
Post-traumatic arthritis (especially with intra-articular involvement)
Complex regional pain syndrome (CRPS)
Tendon irritation or rupture

16. Treatment Plan

Initial stabilization (ED)

Analgesia: hematoma block or procedural sedation for reduction
Closed reduction: Apply longitudinal traction, then dorsally directed pressure on the volar-displaced distal fragment to restore alignment. Unlike Colles' reduction, the wrist should be immobilized in slight dorsiflexion and supination to counteract the volar deforming forces
Apply a well-molded sugar-tong splint after reduction[1]
Post-reduction PA and lateral radiographs to confirm acceptable alignment

Acceptable reduction parameters

Radial shortening ≤2–3 mm
Volar/dorsal tilt <10°
Intra-articular step-off ≤2 mm
Congruent DRUJ

Operative management: Smith's fractures frequently require surgical fixation due to inherent instability. Volar locking plate fixation is the most commonly used technique, providing earlier functional recovery.[7] Operative treatment is recommended for non-geriatric patients (<65 years) with fractures that do not meet acceptable reduction parameters.[14-15] In patients >65 years, strong evidence shows no difference in patient-reported outcomes between operative and non-operative treatment.[15]

Post-operative: Removable wrist brace, early digit ROM, multimodal analgesia.[7]

17. Disposition

Discharge: Nondisplaced or acceptably reduced fractures with intact neurovascular exam, adequate pain control, and reliable follow-up
Orthopedic consultation in ED: Displaced fractures requiring reduction, concurrent dislocation, open fracture, neurovascular compromise, compartment syndrome[1]
Admission criteria: Open fracture requiring operative washout, acute carpal tunnel syndrome requiring emergent decompression, compartment syndrome, polytrauma
Observation: Consider for patients with borderline neurovascular exam or significant swelling at risk for compartment syndrome
Most Smith's fractures warrant early orthopedic follow-up (within 3–7 days) given the high rate of redisplacement — 28% of conservatively managed distal radius fractures redisplace within 6 weeks[17]

18. Follow Up / Return Precautions

Follow-up: Orthopedic/hand surgery follow-up within 5–7 days for repeat radiographs and reassessment of alignment
Radiographic follow-up at 2 weeks, then as clinically indicated (evidence supports case-by-case radiographic frequency)[7][15]
Immobilization duration: 3–6 weeks depending on fracture stability and healing[1]
Return precautions — instruct patients to return immediately for:
Increasing numbness or tingling in the fingers (especially thumb, index, middle)
Increasing pain despite medication, or pain with passive finger extension
Fingers turning blue, white, or cold
Inability to move fingers
Splint becoming too tight from swelling
Fever, drainage, or foul odor from the splint
Expected recovery: Most patients regain functional wrist motion by 3–6 months. Grip strength recovery may take up to 12 months. Consider osteoporosis evaluation and fall prevention in elderly patients with fragility fractures.

References

1. Common Fractures of the Radius and Ulna. — Patel DS, Statuta SM, Ahmed N. American Family Physician. 2021.

2. Operative Treatment of Smith-Goyrand Fractures. — van Leeuwen PA, Reynders PA, Rommens PM, Broos PL. Injury. 1990.

3. Smith's Fracture Generally Occurs After Falling on the Palm of the Hand. — Matsuura Y, Rokkaku T, Kuniyoshi K, et al. Journal of Orthopaedic Research : Official Publication of the Orthopaedic Research Society. 2017.

4. Acute Carpal Tunnel Syndrome and Median Nerve Neurapraxia: A Review. — Holbrook HS, Hillesheim RA, Weller WJ. The Orthopedic Clinics of North America. 2022.

5. Best Practices In The Management Of Orthopaedic Trauma. — Matthew L. Davis MD FACS, Gregory J. Della Rocca MD PhD FACS, Megan Brenner MD MS RPVI FACS, et al American College of Surgeons (2015). 2015.

6. Diagnosis and Treatment of Acute Extremity Compartment Syndrome. — von Keudell AG, Weaver MJ, Appleton PT, et al. Lancet. 2015.

7. Practical Application of the 2020 Distal Radius Fracture AAOS/ASSH Clinical Practice Guideline: A Clinical Case. — Kamal RN, Shapiro LM. The Journal of the American Academy of Orthopaedic Surgeons. 2022.

8. Impact of Bone Density on Distal Radius Fracture Patterns and Comparison Between Five Different Fracture Classifications. — Lill CA, Goldhahn J, Albrecht A, et al. Journal of Orthopaedic Trauma. 2003.

9. 'Ao' or Eponyms: The Classification of Wrist Fractures. — Thurston AJ. ANZ Journal of Surgery. 2005.

10. The Evaluation of the Sensitivity and Specificity of Wrist Examination Findings for Predicting Fractures. — Eyler Y, Sever M, Turgut A, et al. The American Journal of Emergency Medicine. 2018.

11. ACR Appropriateness Criteria® Major Blunt Trauma: Update 2025. — Expert Panel on Polytrauma Imaging, Lee JT, Camacho MA, et al. Journal of the American College of Radiology : JACR. 2026.

12. Classification Systems for Distal Radius Fractures. — Kleinlugtenbelt YV, Groen SR, Ham SJ, et al. Acta Orthopaedica. 2017.

13. Fracture of the Distal Radius: Classification of Treatment and Indications for External Fixation. — Graff S, Jupiter J. Injury. 1994.

14. Management of Distal Radius Fractures: Evidence-Based Clinical Practice Guideline. — American Academy of Orthopaedic Surgeons (2020). 2020.

15. American Academy of Orthopaedic Surgeons/American Society for Surgery of the Hand Clinical Practice Guideline Summary Management of Distal Radius Fractures. — Kamal RN, Shapiro LM. The Journal of the American Academy of Orthopaedic Surgeons. 2022.

16. Percutaneous Pinning for Treating Distal Radial Fractures in Adults. — Karantana A, Handoll HH, Sabouni A. The Cochrane Database of Systematic Reviews. 2020.

17. Volar Plate Fixation Versus Plaster Immobilization in Acceptably Reduced Extra-Articular Distal Radial Fractures: A Multicenter Randomized Controlled Trial. — Mulders MAM, Walenkamp MMJ, van Dieren S, et al. The Journal of Bone and Joint Surgery. American Volume. 2019.