1. Common Pediatric Fractures Allyson S. Howe, MD Maj, USAF, MC

2. INTRODUCTION ANATOMY OF THE GROWING BONE ANATOMY OF THE GROWING BONE INJURY PATTERN OF BONE INJURY PATTERN OF BONE PHYSEAL INJURIES PHYSEAL INJURIES SPECIFIC SITES SPECIFIC SITES DISTAL RADIUS DISTAL RADIUS ELBOW ELBOW CLAVICLE CLAVICLE TIBIA TIBIA CHILD ABUSE CHILD ABUSE

3. RELEVANCE Nearly 20% of children who present with an injury have a fracture Nearly 20% of children who present with an injury have a fracture 42% boys, 27% girls will sustain fracture in childhood 42% boys, 27% girls will sustain fracture in childhood

4. ANATOMY OF GROWING BONE Epiphysis Epiphysis Physis Physis Metaphysis Metaphysis Diaphysis Diaphysis Periosteum Periosteum

5. INJURY PATTERN IN GROWING BONES Bones tend to BOW rather than BREAK Bones tend to BOW rather than BREAK Compressive force= TORUS fracture Compressive force= TORUS fracture Aka. Buckle fracture Aka. Buckle fracture Force to side of bone may cause break in only one cortex= GREENSTICK fracture Force to side of bone may cause break in only one cortex= GREENSTICK fracture The other cortex only BENDS The other cortex only BENDS In very young children, neither cortex may break= PLASTIC DEFORMATION In very young children, neither cortex may break= PLASTIC DEFORMATION

6. INJURY PATTERN IN GROWING BONES Bones tend to BOW rather than BREAK Bones tend to BOW rather than BREAK Compressive force= TORUS fracture Compressive force= TORUS fracture Aka. Buckle fracture Aka. Buckle fracture Force to side of bone may cause break in only one cortex= GREENSTICK fracture Force to side of bone may cause break in only one cortex= GREENSTICK fracture The other cortex only BENDS The other cortex only BENDS In very young children, neither cortex may break= PLASTIC DEFORMATION In very young children, neither cortex may break= PLASTIC DEFORMATION

7. INJURY PATTERN IN GROWING BONES Bones tend to BOW rather than BREAK Bones tend to BOW rather than BREAK Compressive force= TORUS fracture Compressive force= TORUS fracture Aka. Buckle fracture Aka. Buckle fracture Force to side of bone may cause break in only one cortex= GREENSTICK fracture Force to side of bone may cause break in only one cortex= GREENSTICK fracture The other cortex only BENDS The other cortex only BENDS In very young children, neither cortex may break= PLASTIC DEFORMATION In very young children, neither cortex may break= PLASTIC DEFORMATION

8. INJURY PATTERN IN GROWING BONES Bones tend to BOW rather than BREAK Bones tend to BOW rather than BREAK Compressive force= TORUS fracture Compressive force= TORUS fracture Aka. Buckle fracture Aka. Buckle fracture Force to side of bone may cause break in only one cortex= GREENSTICK fracture Force to side of bone may cause break in only one cortex= GREENSTICK fracture The other cortex only BENDS The other cortex only BENDS In very young children, neither cortex may break= PLASTIC DEFORMATION In very young children, neither cortex may break= PLASTIC DEFORMATION

11. INJURY PATTERNS CON’T Point at which metaphysis connects to physis is an anatomic point of weakness Point at which metaphysis connects to physis is an anatomic point of weakness Ligaments and tendons are stronger than bone when young Ligaments and tendons are stronger than bone when young Bone is more likely to be injured with force Bone is more likely to be injured with force Periosteum is biologically active in children and often stays intact with injury Periosteum is biologically active in children and often stays intact with injury This stabilizes fracture and promotes healing This stabilizes fracture and promotes healing

12. INJURY PATTERNS CON’T Point at which metaphysis connects to physis is an anatomic point of weakness Point at which metaphysis connects to physis is an anatomic point of weakness Ligaments and tendons are stronger than bone when young Ligaments and tendons are stronger than bone when young Bone is more likely to be injured than soft tissue Bone is more likely to be injured than soft tissue Periosteum is biologically active in children and often stays intact with injury Periosteum is biologically active in children and often stays intact with injury This stabilizes fracture and promotes healing This stabilizes fracture and promotes healing

13. PHYSEAL INJURIES Many childhood fractures involve the physis Many childhood fractures involve the physis 20% of all skeletal injuries in children 20% of all skeletal injuries in children Can disrupt growth of bone Can disrupt growth of bone Injury near but not at the physis can stimulate bone to grow more Injury near but not at the physis can stimulate bone to grow more

14. SALTER HARRIS Classification system to delineate risk of growth disturbance Classification system to delineate risk of growth disturbance Higher grade fractures are more likely to cause growth disturbance Higher grade fractures are more likely to cause growth disturbance Growth disturbance can happen with ANY physeal injury Growth disturbance can happen with ANY physeal injury

15. SALTER HARRIS CLASSIFICATION I Fracture passes transversely through physis separating epiphysis from metaphysis Fracture passes transversely through physis separating epiphysis from metaphysis II II III III IV IV V

16. SALTER HARRIS CLASSIFICATION I II II Transversely through physis but exits through metaphysis Transversely through physis but exits through metaphysis Triangular fragment Triangular fragment III III IV IV V

17. SALTER HARRIS CLASSIFICATION I II II III III Crosses physis and exits through epiphysis at joint space Crosses physis and exits through epiphysis at joint space IV IV V

18. SALTER HARRIS CLASSIFICATION I II II III III IV IV Fracture extends upwards from the joint line, through the physis and out the metaphysis Fracture extends upwards from the joint line, through the physis and out the metaphysis V

19. SALTER HARRIS CLASSIFICATION I II II III III IV IV V Crush injury to growth plate Crush injury to growth plate

20. PHYSEAL FRACTURES MOST COMMON: Salter Harris ___ MOST COMMON: Salter Harris ___

21. PHYSEAL FRACTURES MOST COMMON: Salter Harris _II_ MOST COMMON: Salter Harris _II_ Followed by I, III, IV, V Followed by I, III, IV, V Refer to ortho III, IV, V Refer to ortho III, IV, V I and II effectively managed by primary care with casting (most commonly) I and II effectively managed by primary care with casting (most commonly) Don’t forget to tell Mom and Dad that growth disturbance can happen with any physeal fracture Don’t forget to tell Mom and Dad that growth disturbance can happen with any physeal fracture

22. IT’S GOOD TO BE YOUNG Children tend to heal fractures faster than adults Children tend to heal fractures faster than adults Advantage: shorter immobilization times Advantage: shorter immobilization times Disadvantage: misaligned fragments become “solid” sooner Disadvantage: misaligned fragments become “solid” sooner Anticipate remodeling if child has > 2 years of growing left Anticipate remodeling if child has > 2 years of growing left Mild angulation deformities often correct themselves Mild angulation deformities often correct themselves Rotational deformities require reduction (don’t remodel) Rotational deformities require reduction (don’t remodel)

23. IT’S GOOD TO BE YOUNG Fractures in children may stimulate longitudinal bone growth Fractures in children may stimulate longitudinal bone growth Some degree of bone overlap is acceptable and may even be helpful Some degree of bone overlap is acceptable and may even be helpful Children don’t tend to get as stiff as adults after immobilization Children don’t tend to get as stiff as adults after immobilization After casting, callus is formed but still may be fibrous After casting, callus is formed but still may be fibrous Avoid contact activities for 2-4 weeks once out of cast Avoid contact activities for 2-4 weeks once out of cast

24. COMMON FRACTURES Distal radius Distal radius Elbow Elbow Clavicle Clavicle Tibia Tibia

25. DISTAL RADIUS Peak injury time correlates with peak growth time Peak injury time correlates with peak growth time Bone is more porous Bone is more porous Most injuries result from FOOSH Most injuries result from FOOSH Check sensation: median and ulnar nerve Check sensation: median and ulnar nerve Nerve injury more likely to occur with significant angulation of fragment or with significant swelling Nerve injury more likely to occur with significant angulation of fragment or with significant swelling Examine elbow (supracondylar) and wrist (scaphoid) Examine elbow (supracondylar) and wrist (scaphoid)

26. DISTAL RADIUS Torus fractures Torus fractures Usually nondisplaced- strong periosteum Usually nondisplaced- strong periosteum Subtle, may be best seen on lateral Subtle, may be best seen on lateral Greenstick fractures Greenstick fractures Compression of dorsal cortex, apex volar angulation Compression of dorsal cortex, apex volar angulation Complete (transverse) fractures Complete (transverse) fractures

27. TORUS FRACTURES No reduction needed No reduction needed If > 48 hours old, ok to cast at first visit If > 48 hours old, ok to cast at first visit Otherwise splint and cast at 5-7 days Short arm cast for 4 weeks Short arm cast for 4 weeks Repeat x-rays unnecessary unless no clinical improvement after 4 weeks Repeat x-rays unnecessary unless no clinical improvement after 4 weeks Splint an additional 2 weeks Splint an additional 2 weeks

28. GREENSTICK FRACTURES If non-displaced If non-displaced Short arm cast If displaced >15 degrees, reduce and immobilize in long arm If displaced >15 degrees, reduce and immobilize in long arm 4 weeks cast, 2 weeks splint 4 weeks cast, 2 weeks splint

29. DISTAL RADIUS PHYSIS FRACTURE Non-displaced Salter I can appear normal on plain films Non-displaced Salter I can appear normal on plain films Presence of pronator fat pad along volar distal radius on lateral film = occult fracture Presence of pronator fat pad along volar distal radius on lateral film = occult fracture If tender over physis, treat as fracture If tender over physis, treat as fracture

30. SALTER HARRIS II SALTER HARRIS II

31. DISTAL RADIUS FRACTURES Displaced fractures= reduce asap Displaced fractures= reduce asap Non-displaced fractures= short arm cast for 3-6 weeks Non-displaced fractures= short arm cast for 3-6 weeks The older the child, the longer immobilization The older the child, the longer immobilization If x-rays are normal initially but tenderness is over growth plate, immobilize for 2 weeks If x-rays are normal initially but tenderness is over growth plate, immobilize for 2 weeks Bring child back to re-examine and re-xray Bring child back to re-examine and re-xray If no callus, fracture is unlikely If no callus, fracture is unlikely

33. ELBOW 10% of all fractures in children 10% of all fractures in children Diagnosis and management complex Diagnosis and management complex Early recognition and referral Early recognition and referral Most are supracondylar fractures Most are supracondylar fractures Sequence of ossification: Sequence of ossification: Come Read My Tale Of Love Come Read My Tale Of Love Capitellum, Radial head, Medial epicondyle, Trochlea, Olecranon, Lateral epidondyle Capitellum, Radial head, Medial epicondyle, Trochlea, Olecranon, Lateral epidondyle Age 1, 3, 5, 7, 9, 11 Age 1, 3, 5, 7, 9, 11

34. ELBOW FRACTURE EXAMINATION Check neurovascular status Check neurovascular status Flex and extend fingers and wrist Flex and extend fingers and wrist Oppose thumb and little finger Oppose thumb and little finger Palpate brachial and radial pulses Palpate brachial and radial pulses Capillary refill in fingers Capillary refill in fingers Immobilize elbow before radiographs to avoid further injury from sharp fragments Immobilize elbow before radiographs to avoid further injury from sharp fragments Flexion 20-30 degrees = least nerve tension Flexion 20-30 degrees = least nerve tension

36. Know basic landmarks on lateral view to give clues to distinguish fracture from normal Anterior humeral line— middle 1/3 capitellum Anterior humeral line— middle 1/3 capitellum Radiocapitellar line— points directly to capitellum Radiocapitellar line— points directly to capitellum Disruption = displaced fracture Disruption = displaced fracture Fat pad sign may be only clue if non-displaced Fat pad sign may be only clue if non-displaced

37. Fat Pad sign (aka. Sail Sign) Fat Pad sign (aka. Sail Sign) Anterior fat pad sign can be normal Posterior always abnormal

38. SUPRACONDYLAR FRACTURES Weakest part of the elbow joint where humerus flattens and flares Weakest part of the elbow joint where humerus flattens and flares Most common fracture is extension type Most common fracture is extension type Olecranon driven into humerus with hyperextension Olecranon driven into humerus with hyperextension Marked pain and swelling of elbow Marked pain and swelling of elbow Potential for vascular compromise Potential for vascular compromise Check pulse!!! Reduce fracture if pulse compromised Check pulse!!! Reduce fracture if pulse compromised Check nerve function in hand Check nerve function in hand

39. SUPRACONDYLAR FRACTURE CLASSIFICATION Type I- non-displaced or minimally displaced Type I- non-displaced or minimally displaced Type II- displaced distal fragment with intact posterior cortex Type II- displaced distal fragment with intact posterior cortex Type III- displaced with no contact between fragments Type III- displaced with no contact between fragments

40. Anterior Humeral Line Radiocapitellar Line Radiocapitellar Line

45. SUPRACONDYLAR FRACTURES MANAGEMENT Most are displaced and need surgery Most are displaced and need surgery Type I can be managed with long arm cast, forearm neutral, elbow 90 o for 4 wks Type I can be managed with long arm cast, forearm neutral, elbow 90 o for 4 wks Bivalve cast if acute Bivalve cast if acute Follow-up xrays 3-7 days later to document alignment Follow-up xrays 3-7 days later to document alignment Xrays at 4 weeks to document callus Xrays at 4 weeks to document callus Once callus noted at 4 weeks, discontinue cast and start active ROM Once callus noted at 4 weeks, discontinue cast and start active ROM

46. SUPRACONDYLAR FRACTURES COMPLICATIONS Malunion Malunion Often varus deformity at elbow with loss of full extension (“gunstock” deformity) Often varus deformity at elbow with loss of full extension (“gunstock” deformity) Cosmetic concerns, usually no functional deficit Cosmetic concerns, usually no functional deficit

47. LATERAL CONDYLAR FRACTURES Second most common elbow fracture Second most common elbow fracture Most common physeal elbow injury Most common physeal elbow injury FOOSH + Varus force = lateral condyle avulsion FOOSH + Varus force = lateral condyle avulsion Exam: focal swelling at lateral distal humerus Exam: focal swelling at lateral distal humerus

48. LATERAL CONDYLAR FRACTURES Most common x-ray findings: Most common x-ray findings: Fracture line begins in distal humeral metaphysis and extends to just medial to capitellar physis into the joint Fracture line begins in distal humeral metaphysis and extends to just medial to capitellar physis into the joint Neurovascular injury rarely Neurovascular injury rarely MEDIAL MEDIAL LATERAL LATERAL

49. LATERAL CONDYLAR FRACTURES MANAGEMENT Intraarticular = open reduction Intraarticular = open reduction If non-displaced, can treat with casting If non-displaced, can treat with casting Posterior splint acutely, elbow 90 o Posterior splint acutely, elbow 90 o At follow-up (weekly), check for late displacement At follow-up (weekly), check for late displacement If stable x 2 weeks, long arm cast for another 4-6 weeks If stable x 2 weeks, long arm cast for another 4-6 weeks Complications: growth arrest, non-union Complications: growth arrest, non-union

51. CLAVICLE Most occur in the _____ third of the bone Most occur in the _____ third of the bone

52. CLAVICLE Most occur in the middle third of the bone Most occur in the middle third of the bone 80% 80% 15% distal third, 5% proximal third 15% distal third, 5% proximal third FOOSH, fall on shoulder, direct trauma FOOSH, fall on shoulder, direct trauma Clinical: pain with any shoulder movement, holds arm to chest Clinical: pain with any shoulder movement, holds arm to chest Point tender over fracture, subQ crepitus Point tender over fracture, subQ crepitus Often obvious deformity Often obvious deformity

53. CLAVICULAR FRACTURE AP view often sufficient to diagnose if midshaft AP view often sufficient to diagnose if midshaft Consider 45 o cephalic tilt view if needed Consider 45 o cephalic tilt view if needed

54. CLAVICULAR FRACTURE In displaced fracture: sternocleidomastoid pulls upward to displace medial clavicle, lateral fragment pulled downward by weight of arm In displaced fracture: sternocleidomastoid pulls upward to displace medial clavicle, lateral fragment pulled downward by weight of arm

56. CLAVICULAR FRACTURE MANAGEMENT Sling versus figure-of-eight bandage Sling versus figure-of-eight bandage Fracture fully healed when pt has painless ROM at shoulder and non tender to palpation at fracture Fracture fully healed when pt has painless ROM at shoulder and non tender to palpation at fracture Generally back to full activity by 4 weeks Generally back to full activity by 4 weeks Protect from contact sports x 6 weeks Protect from contact sports x 6 weeks Warn of the healed ‘bulge’ Warn of the healed ‘bulge’

58. TIBIA Tibia and fibula fractures often occur together Tibia and fibula fractures often occur together If you see a tibial fracture, hunt for a fibular one If you see a tibial fracture, hunt for a fibular one Fibular fracture could be plastic deformity Fibular fracture could be plastic deformity Mechanism: falls and twisting injury of the foot Mechanism: falls and twisting injury of the foot Low force, intact periosteum and support from fibula prevent displacement commonly Low force, intact periosteum and support from fibula prevent displacement commonly

59. TIBIAL FRACTURE When to refer: When to refer: Displaced fracture Tib/fib fractures Fractures with > 15 o varus angulation

60. TIBIAL FRACTURE MANAGEMENT Posterior lower leg splint if acute Posterior lower leg splint if acute Non-displaced fractures: long leg cast for 6-8 weeks Non-displaced fractures: long leg cast for 6-8 weeks Repeat radiographs weekly to check position Repeat radiographs weekly to check position Refer if angulates more than 15 o Refer if angulates more than 15 o

61. TODDLER’S FRACTURES Children younger than 2 years old learning to walk Children younger than 2 years old learning to walk No specific injury notable most of the time No specific injury notable most of the time Child refuses to bear weight on leg Child refuses to bear weight on leg Examine hip, thigh and knee to r/o other causes of limping Examine hip, thigh and knee to r/o other causes of limping

62. TODDLER’S FRACTURES If you suspect it, get AP and lateral views of entire tib/fib area If you suspect it, get AP and lateral views of entire tib/fib area Typical: nondisplaced spiral fracture of tibia with no fibular fracture Typical: nondisplaced spiral fracture of tibia with no fibular fracture Initial x-ray often normal, diagnosis on f/u films with lucent line or periosteal reaction Initial x-ray often normal, diagnosis on f/u films with lucent line or periosteal reaction

63. TODDLER’S FRACTURES Consider and rule out abuse when needed Consider and rule out abuse when needed Examine for soft tissue injury to buttocks, back of legs, head, neck Examine for soft tissue injury to buttocks, back of legs, head, neck Transverse fractures of mid-shaft are more suspicious for child abuse Transverse fractures of mid-shaft are more suspicious for child abuse Management: long leg cast x 3-4 weeks Management: long leg cast x 3-4 weeks Weight bearing as tolerated Weight bearing as tolerated Heals completely in 6-8 weeks Heals completely in 6-8 weeks

64. FRACTURES OF ABUSE Majority of fractures in child < 1 year are from abuse Majority of fractures in child < 1 year are from abuse High percentage of fractures <3yo = abuse High percentage of fractures <3yo = abuse Greater risk of abuse: first-born, premature infants, stepchildren, children with learning or physical disabilities Greater risk of abuse: first-born, premature infants, stepchildren, children with learning or physical disabilities Most common sites: femur, humerus, tibia Most common sites: femur, humerus, tibia Also: radius, skull, spine, ribs, ulna, fibula Also: radius, skull, spine, ribs, ulna, fibula

65. Child Abuse Concerns Unexplained fractures in different stages of healing as shown on radiology Unexplained fractures in different stages of healing as shown on radiology Femoral fracture in child < 1 year Femoral fracture in child < 1 year Scapular fracture in child without a clear history of violent trauma Scapular fracture in child without a clear history of violent trauma Epiphyseal and metaphyseal fractures of the long bones Epiphyseal and metaphyseal fractures of the long bones Corner or “chip” fractures of the metaphyses Corner or “chip” fractures of the metaphyses

66. CHILD ABUSE If suspected, skeletal survey should be considered If suspected, skeletal survey should be considered Bone scan may be useful as complementary study Bone scan may be useful as complementary study

67. CONCLUSIONS Nearly 20% of children with injury have a fracture Nearly 20% of children with injury have a fracture Always take post-reduction x-rays Always take post-reduction x-rays Physeal injuries are common and may have no radiographic findings Physeal injuries are common and may have no radiographic findings Treat as fracture!! Treat as fracture!! Don’t forget to tell Mom and Dad about possible growth problems Don’t forget to tell Mom and Dad about possible growth problems