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Clinical Anatomy and Management of Cervical Spine Pain
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CLINICAL ANATOMY AND .MANAGEME
T OF
CERVICAL SPINE PAIN
L. G. F. Giles MSc, DC(C), PhD Department of Public James
University
and Tropical Jledlcine,
Queenslond, 1i!1L'nsville
Director National Centre for Multidisciplinary Studies of Back Pain, Townsville General Hospital
Honorary Clinical Scientist Townsville General Hospitai, TOIl'lIsville, Queensill/ui, Australia
K. P. Singer MSc, PT, PhD Associate Professor School ofPh),siotberapy, Curtin Universil), of Technology, Shenton ParA?, I¥i'stern Australia
Honorary Research Fellow Departments of Radiology, Ne u ropathology and Bioe ngi neering , Royal Perth Hospital, Perth, Western Australia, Australia
With
Professor
Foreword by
Dvorak
Head of Departmen t of Neurology,
Sp ine Unit, Schultbess Clinic, Zu rich, Switzerland
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Bu rterworth-Heine man n Linacrc I-Iollse, Jordan HiJl, Oxford OX2 8DP
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A member of the Reed Elsevier pic group
OXI·ORD
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Copyrighted Material
( l 990).
J 6 Clinical A natomy and Management of Cervical Spine Pain and Otber Disorders ()J the Cervical Spine.
Summary
WB Saunders. Bra i n , W. R . , Northfie l d . t h e possible c a u s e s o f
It is n o t o u r n e c k pain
s u m m a rising some anatomy
and p a t h o l ogy
a bearing on c e rv i c a l
s p i n e p a in
b u t ra ther to p rovid e
a n overvic\\
hSlI e as an in trodu ction
to fo llowing
to appre ciate a n e c k symptoms, it is n e cessary to
p a i n sufferer's
u n de rsta n d n o r m a l erect posture and the c o m p lex a na to m y and possi b l e s u b t l e o r overt p a t h o logy o f the c e rvical spine and the cervicothora c ic j u nc t i o n (see C h a p ters 2 and
3) . The
foll o w i n g chapters review t h e
b as ic a na t o my a n d p a t h ology o f the c e r v ic a l s p i n e , fo l lowed
by
w h i p l ash-type
k i n e m a ti c s , i n j u ries,
the
c l i n ic a l
rad i o logy
picture
and
of
c li n ic a l
manage m e n t .
References Outline oj OrthojJaedics. Adams, Je. . Livingstone, p . 1 5 4 . 1 1 th edn. Adams, M A . W e . (1 986) T h e stages of d isc dege n e ra t i o n a s reve a l e d by d i scogram . ] Bone join/ Surg. 688: 36. AI-Mefry, 0. , Borba, A . B . , Aoki, N., Anglu3co, E . , Pa i t , TG. ( 1 996) The tran scondylar a pproach to ex t radura l n o n neoplastic lesions of t h e c ra n i overte b ra l junction . ] Neul'Osarg. 84: 1 - 6 . And e rsson , G . B .J. ( I 983) T h e biomechanics o f t h e posterior e lements of t h e lumbar spine. Spine 8: 326. S Vest i n g R A . et a!. ( 1 995) Anatomic Ba i l ey, A . S . , re l a tionsllip, i l o racic junction. Spine 20: 143 1- 1 Ba rnsley, L . ( 1 993) The p a thop hysioJ ogy of Hex/on - Extensions/Whip Sh apiro, eds) . Spine: Stat, lash Injuries of the Art Philad e l p h i a : H a nl e y a n d BeJius, pp. 329 · B a rr, M . L . , The Human Nervous ,\)stem, 4 th e d n . Philade lp h i a : l-l a r p e r & Row. B e n so n , D. R . ( 1 983) The spine a n d nec k . I n ilfusculoskele tal Diseases oj Children (Ge r s hw i n '''I . E , Robbins D . L , eds). New York: Gru n e & St ra tto n , p. 469 B l a n d , J H ( 1 987) Disorders oj the Cervical Sp ine Diag nosis and Medical Management: P h ilad e l p h i a WB Saunders. Bogd u k , "i. ( 1 99 5) Ed itori a l . Scie nritlc monogra ph of the associated supplementary Quebec d isorders. Bog d u k , N. , ( l 988) The in nerva t i o n of cervical Spine 1 3 : 2 - 8. Boh l m a n , H I spondylosis and myelopathy r.eaures Qackson D.W. , ed.) S u rgeo ns, pp. 81 - 97. o f myofascial p a i n syn Bonica, J.J. ( I d romes i n general practice. I I . M.A. 1 6 4 : 73 2 - 738. Bovlm , G. , Schrader, H., Sa n d , T. ( 1 994) Neck pain in the generA l populati o n . SjJine 1 9 : 1 307- 1 3 09 Brd i n , L. , Wi l ki n so n , M . (eds) ( 1 967) Cervical SpondylosiS
Philadelph i a :
D. , Wi l ki nson, M . (1 95 2) The of cerv t ( :iI
m a n ifestat i o n s
1 8 '-225. \1ill e r, C A . , R e a , G . L . e l al J1ll:lging of t ra u m a to the rhol':! ,.ic 17: 54 1 - 5 50 It m pleton, A.W, H odges . acqui red and con ge n i r;d A.jR. 92: 1 2 5 5 - 1 2 59 B u i rski , G . , S i l berste i n , M . (1 993) The symptomatiC Ilimba r d isc i n patients with l ow-back pa i n. ,SjJine 1 8 : 1 808 - 1 8 1 1 . Bu tler, D. , Tratl m ow, J H , And ersson, G . B ../. et al. ( 1 990) D iscs dege n e l�lte befo re facets. Spine 1 5 : J 1 1 - 1 1 3. Cai l l ier, R. ( 1 968) Low Back Pa in Sy ndro me, 2 n d e dn . Philadelphia: F A . Davis Carpenter, R . L. , Ra uck. R. L ( l 996) Refractory head and ot>ck p a i n A d iftic u l r problem a n d a new a l rernati ve A nesthesiology 84: 249 - 2 52. I. 1 1')87) Spectrophotometric i n osteoa rth r i t i c synO\ l :l 1 "16: 375 - 379 1')')5) Cervical c e n t r a l cord trigemin a l n u c l e u s : a 2 16 - 240 ( I ')H5) Correiatil'e Neuroana/r'IJI F tiona! Neurology, 1 9 t h cdn. Ca l iforn i a : l.ange M e di c a l Pu blications, p. 1 6 2 . Clarke, E. , Rob inso n . P K . ( 1 956) Cervical myeloparhy: a complication of cervica l spondylOSiS, Brain 79: 4 83 - 5 1 0. Compere, E.L. , Tac hcl j i a n , M .O . , Kcrna[lan, WT. ( l 9 5 9) The Luschka j o i n ts . Their a n a tomy, ph y s i ol ogy a nd pathology. A m. ] Or /b op. Surg. 1 : 1 "9 - 1 68 Day, LJ. , Bovill, E . G . , Trafton, P C; . e/ Cli ( 1 994) O rthopedics. r n: (:11 rnm t Su rg ica l Diagnosis and Trea tm(,l1 t (\X'JY L W. Appleton Lange , pp. 1 0 I - I ) (] 980) Diagnosis of low back In: Tue Lumbar Spine ed.), 2nd e d n . Kent: D. , Pen n ing, L et al. ( I diagnosis of the cervical IjJine 13: 74 8 -7 5 5 . D y c k , f> ( 1 98 5) Pa raplegia fo l lowi ng chemonucleolysis. Spine 10: 359. Eguro, H . ( 1 983) TI�lIl sverse mye l i ti S fol l owing chema n ucleolysis. ] BoY/e join! SlIIg. 6 5A: 1 328. Eisenstein, S . M . , Pa rr)" e . R ( l ')87) The I limba r facet a rthrosis synd rom e . C li n i c a l presenta t i o n a n d a rticul a r su rface changes. J Bone j()int Stng 698: 3 -7 . EI-Khou ry, G . Y , Renfrew, D.L. ( 1 99 1 ) Pe rclitaneOllS p roce d i agnosis and t reatment of [';lcet j o i n t inj e c t i o n , and 61-;5 - 69 1 . Epste in , ]. A . ( 1 987) I nd ivid ual cerv i c a l spinal stenosis. I n Spine : S t a t e o f the ( I 'PH) The biomechanical adval1tJ,Qt h i p e(lel.15ion for u p r i g h t m a n '" othe r anthropoids. Spine 3: 3 ,, 6 - 3 4 5 . Fa rfa n , H . E ( 1 980) T h e sc i e n t ifk b a s i s of m a n i pula t i ve p rocedures . CUn. Rbeurn. /Jis. 6: 1 59 - 1 78 .
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Management of Cervical Spine
18 Clinical sil1atomy M a rgo,
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p a ti e n ts w i t h l o w back p ai n . A m . Fam. Physicia n
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M .J,
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and
7, 4 2 3 - 4 4 1 . ilk:v!. (196m
Bosto n :
Manipalalil '/? Techniques
P" osp e c t i ve
:111 0
c o r re l a t i o n
of
asympto
c! iscogra phl
2 : ,00 - 3 1 2 .
( 1 9�S) ,l1antpulalion Past and
Present. Lo n d o n : Heinelll31lJl Medica l .
H.
Schmorl , G . , JlI ng h a n m , S t ra t t o n , p p .
Pain DiagnosiS and
( 1 97 1 ) The Human Sp ine in
2nd
edn.
New York:
&
Grune
, 1 48 , 1
( 1 9,)(» D i scovery the a u to n o m t c n e rvous I. 5 . :\'(,U)'I)/. PsycfJirrlry 35: 1 08 1
D.
syste m . A rch.
M crskey, H . ( 1 993) Psyc h o logi c a l consequen ces o f w h i p l a s h . I n : Cervical Flexion -Extension/Whiplasb Injuries (Te a se l l
R.W.
Reviews
S h a pi ro .A. P , c d s) . S p i n e ' State o f t h e Art
S h e ! o kov,
B.
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256: 3 1 7 R . W. , Jones,
O i sease (R eg11l
c h e m o n uc!eolysis
R.H.
( 1 99 1 )
16,
Construct
validity
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-H38.
( 1 9 5 2)
t r u n k s . Nature
1 29 :
ext re mi t ic' o f sym p a t h e t i c 533 - 53 4 .
OliS System, Edi o b u rgh
L i v i ngstone.
01
( 1 9 3 5 ) H e r n i a tion o r r u p ture
in terve rtebra l d i s c i n to the spin a l c a n a l .
lhe
N Engl ] Med .
385 - .
It!
H e rzog,
( 1 994)
ima g i n g m o d a l i t i e s . o rd e r
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the A rt Reviews
Meet. 73: 5 5 - J 08 . F.J (l 9 9 4 ) Trearme n r of a c u te i nj u ry of the c e rv i c a l s p i n e . ] Bon ejoint Surg 76: 1 882 - 1 896 ( 1 99 5 ) W.O. , S koHo n , M . L . L R. I'orce Oil S c i e n tific monogra p h of A.V,
Eism o n t ,
whi p l a s h-asso c i " t"'..! d is o rd e r s : rcd e fU1 ing ' W hl P l a s h " and
H.A.
S t e in e r,
( 1 94 3)
20:
(BS ) .
R oe n tgenologic
m a n i fe s t a t i o n s
A Pre-clin lrlli View Of Osteoartbritis
and
who , h m1id
(]
S u n d e r la n d , S .
1 9 : ] -(,1 - 1 76 5 .
An a to m ic:ti perivertebrct l I nfl uence,
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Spinal
Attst. Prescriber 1 7 :
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9 - 1 2.
Nachemso n , A . L . ( 1 911 5 ) Advances in low-back p a in, elin.
Manipulative M o n ograp h
Tberapy no.
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(Go l d s t e i n
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266 - 2'7r;
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Edin
E.S. Liv i n g s t o n e .
corner
avail a b l e
40:
Medical S c h oo l .
( 1 99 4 ) T h e n o n p h a r m acological t r ea t m e n t o f
N a t i o n al
Q) 0 Q) 0> C
«
Facet angle
100 .-------.---,
125 90 120 115
80
110 70
...... F -O-M
105
B
100
60 C6
C7
T1
T2
T3
T4
C6
C7
T1
T2
T3
T4
Vertebral level Fig. 3.3 Changes in orientation of the superior articular processes (zygapophysial joints) through the cervicothorJcic junction (C6-T4) using mean data from 51 cases (Boyle et al., 1996). Data fOf the disc-facet angle is given for males (M) and females (F) separately, while both male and female c1 at a are combined for the mean facet an g le results. A schematic representation of the angles is included (d elisc-fAcet angle, i.ii right and left facet angles). =
=
steady decline from tile C5 -6 mot i on segment to the upper thoracic segments was fo u nd , as depicted in
motion has relatively more tilting and less sliding within the disc ( Lyse II , 1969; Penning, 1988; Milne,
Fig ure 3.4. Due to the oblique orientat i on of the cervical
1993b).
articular facets, motion in the sagittal plane incorpor
cervical articular facets, the movements of rotation
ates some sl i din g as well as tilting within the cervical
and lateral flexion are coupled wi th i n the cervical
discs during flexion and extension. The centre of
spine so that rotation is accompanied by ipsilateral
Again,
due
to
the
oblique
orientation
of
the
rotation in the cervical region is situated well below
lateral f l ex i on. This motion can be considered to
the disc, within the sub j acent vertebral body. As you
occur about a single axis which is perpendicular to
move into the lower cervical and the thoracic motion
the plane of the zygapophysial joints, as seen in rhe lateral projection (pe nn i ng and Wilmink, 1987; Milne, 1993b). As the lower c ervical and thoracic
segments the position of this centre of mo t ion moves close to the intervertebral disc, indicating that the
Segmental ranges of motion and trauma patterns
20
C5-6
cs
C6-7
C6
C7-T1
C7
Tl-2
T1
T2-3
T2
TJ-4
TJ
'0
'00
200
300
Cases
Degrees
Fig. 3.4 Comparison of se gm enta l composite rotation (Milne, 1993b) and combined flexion-extension range of m oti on (White and Panjabi, 1990) for the vertebral segments of the cervicothoracic transition. The reduction in mobility from C5 [0 T3 corresponds with representative data for c ervica l trawna Oefferson, 1 927).
Copyrighted Material
44 Clinical Anatomy and Management of Cervical Spine Pain articular facets become more vertical (Fig. 3.3), the axis
of coupled
become
m ot i on
could
horizontal
more
ex p ec t ed
be
(involving
more
to
l ateral
Spinal curvature and weight transmission
flexion). However, the interfacet angles have been shown to have
a
bearing on the axis of coupled
The th o ra cic kyp h osi s has been shown to be high ly
1980;
motion (Milne, 1993b; Fig. 3.5). At C3 and C4 the
variable in normal
i nterfacet angles a re less than 1800 an d the orienta
Be rnha rdt and Bridwell, 1 9 8 4 ; Singe r et at., 1990b).
individuals (Fon
et
al.,
tion of the axis of coupled motion is c o n strain ed to
Bernhardt a n d Bridwell (1984) s tate that the kyph os i s
n ar ro w band p e rpe n d ic u lar to the facets. in the
in the t h ora c ic spin e us u a l ly starts at T 1- 2 (averaging
a
lower cervic a l and thoracic reg i ons where the interfacet angles are greater than 1800 (F ig. 3.3) the
at each
orientation of the axis of c oup l ed motion can vary
kyp h osis centred around the T6-7 diSC, is reached.
gre a t ly depending o n w h ether t h e app lied force was
Fon et at. ( 1 98 0) rep or t ed that females have a sl igh t ly
a b ou t 10 at that s egmen t) and incremental l y increases segment
c au d al ly until the apex of the
,
greater kyphosis and t ha t the ky p h o si s in both sexes,
axial rotation or lateral flexion.
,
tended to increase s l iglltly with age, with the upper
limits of normal in e l d erly adults being as high as 5 6
°.
In ad d i tion to soft tiss ue ageing, Fo n et al. (1980)
Axes of motion in the cervicothoracic spine
-
speculated that the increased kyphos is i n fema les was d u e to relative physical inactivity, probably related to
occ up ati on and that d e pe n d ent brea sts lUay further ,
accentuate the kyp hotic c urv a ture
.
The articul a r s u rfaces of the c ervical vertebrae not only regu l a t e the dire cti on and type of movement
but,
bec au se
of
their
oblique
inclination,
in
a
ventrodorsal directio n they also transmit the weight ,
of t h e head (Med,
transmission in
the
1973). In i nve s tiga t i ng we ight ce rvi c al
and
up p er
thoracic
regions of t he ver t ebra l co lumn compressive forces ,
are tho ug ht to be tra nsmitted through three para l l e l columns
in t h e cervical spine a n d through two
columns in the thoracic spine (pal and Routal, 1986).
Their st u dy pr o pose d that the transfer of load from the cervical to the upp e r th o ra ci c s p ine occurs at the
tran sition of the cervical and thoracic cu rva tur es
.
Th e y postulate three reasons fo r this: first, that there is a sharp decline in the zygapophysial joint surface area in t he upper thoracic region as co mpare d to t he cervica l regi on ; second, that the p e d ic les at Tl and T2 are l arge co mp a re d to tho se above and are inclined downwards and forwards fr om the lamina to
the bod ies, and finally, that the posterior column becomes more c l o se ly placed to the anterior column. Thus, putatively t h e re is a transfer of we ight transmis sion from th e posterior column in the cervica l region
Fig. 3.5
The axes of coupled
rotation in the cervicothoracic
laterdl flexion spine ee2 T2). -
and axial The solid
lines in dica te the axes of coupled motion when the applied force was rotary,
and
the i nter r upted lines indicate the axes
The
when the applied force was l a t er a l bending.
shaded
sectors indicate the range of p ossibl e orientations that the axes can ta ke. TIle axes
in th e
upper two motion s egments
are constrain e d to a very na r row band. The axes in the lower three
segm ent s
shown
can
take
on
a
wide
range
of
orientation, bu t the range of motion here is qui te limited. However
in
the middle three motion segments
where
disc
degen e rat ion is most frequent there is the greatest rd nge of motion and
the
axes have an intermediate range of possible
ce ntres of cervicothoracic spine.
orientations. The small Circles rep r esen t the rotation for sagittal motion in the Adapted from
M i l ne
(l993b).
to the anterior column in the thoracic region. However, to facilitate weight transmission in this
region a p rop or tiona te increase in t h e surface are a of the ver teb ra l bodies in the u p pe r thoracic spine would b e ex pecte d yet this is not the c ase (B o yle et ,
al., 1996). T his may indicate why this c o uld be an
area
where stress is co n c en trate d
.
Similarly,
one
would po stu l at e that there should be an increase in bone mineral density at the cervicothoracic j unction
.
However, the b one mineral d e n s i ty of the seventh
2
cervical ver tebra (approximately 0.6 g/cm ) is sig nificantly l o wer than the levels above (Curylo et at.,
1996). The bone mineral density further d ecrea se s at l t h e first thoracic vertebra, approximately 0.45 g/cm , and a p p roxinlat e ly 0.35 g/cm2 w e re recorded for the
Copyrighted Material
Clinical anatomy Of the cervicothoracic junction 45
second and third thoracic verte brae (Singer et al.,
1995) Based on these find ings any added stress, due to the
population (Fon et al., 1980; Dalton, 1989; Singer et al., 1990b). G riegel-M orris et at. (1992) also studied altered head
pOS ition ,
su ggestin g that there
is a
rela tion ship between the presence of some postural
putat iv e transfer of weight to the a nterior thoracic column, would be applied to a narrower and more
va ri ations and the i nc i d en ce of pa in . They investi
slender thoracic vertebra with a lower bone mineral
gated 88 healthy subjects, aged 20-50 ye a rs, and
de nsity. It is proposed that, in co mbin ation , these
reported that subj ects with increased kyphosis and
in part, contrib ute to the higher
rounded s h oulders had an increased incidence of
findings
may,
inciden ce of d egen er ative ch anges
in
the zygapophy
interscapular pain. Ad ditional ly those s ubjects with a
sial joints reported at C7- Tl, and to the continui n g high incidence of d i scal degenerative changes repor
fo rward head posture hacl an in creased incidence of
ted in the u pp er thoracic region (Boyle et al., 1997).
cervic a l and int ras capular pains and head ache. There was no relationship, however, between the severity
of the post u ral ab nor mality and the s everi ty and frequency of pain. Oegema and Bradford (1991) posed the hypot hesis
Transitional anomalies
that a decrease in disc space may lead to al t ered mechanics of the zygapophysial j oints a n d that the
The incidence of cervic al ribs is thou ght to be about
1 % of the pop u lation O ones et al.,
1984),
changes in motion a n d/or pressure on th e se joints
with
ma y lead to degenerative change. However, Malmi
approximately one-half of these c ases being bilateral.
vaara et al. (1987), in investigating the thoracolumbar
Jones et at. (1984) repor t that these ribs vary from
region, repor ted that anular di srup tion of the disc
remnants emanating from the seventh cervica l verte
was not related to zy ga pophy si a l joint asymmetry, nor
bra to comp lete ribs a rticul at i ng with the manubrium or first rib. Gladstone and Wakeley (1932) described
was t her e an increas e in zyga pophysi al joi nt osteoar
10
cases
of
ce rvica l
ribs and
rudimenta r y
throsis , a l tho ugh,
at Tl1-12, facet
j oin t asymmetry
first
was associated with m ore OA on the side with the
thoracic ribs. Coup led with a review of the literature, indicated that these anomalies were d evel op m e nta l defects prob ably occurring in the ea rly
more s agit ally oriented facet. This fi nd in g was con
stage of embryonic life. Ano m ali es in the nervous and
joint d egene rat ion affect in g the m ore s a gitaLl y ori
they
vascular systems were frequently associated.
sistent with a re port by Giles (1987),
a necdotal
histo logical
evidence
of
who noted
zygapophysial
ented j o i nt as c o mpared to the joint oriented to the
Variations in the morphology of the first rib may
coronal pl a ne , from an ex aminat ion of the lumbo
have a causative role in thoracic o u tlet s y nd rome. A
sacral trans i tion . Similarly, Farfa n and S ulli van (1967)
thick or abnormally curved first rib m ay comprom is e
reported a high correlation between as ymmetrical
the neurova scular bundle in its passage about this
orientation of the zygapop hysia l joints and the level
region and is often associated with changes in the
of disc pathology,
muscul a r
scalenus
prola pse and the side of the more oblique oriented
anterior ancl meclius. Similarly, an anomaly of the
joint in patien ts with low back pain with sciatica. By
attachments
to
the first
rib ,
and
between the side of disc
clavicle can lead to a pincerlike action between it an d
comparison, Hagg and Walln er (1990), in a study of
tl1e first rib Oones et al., 1984).
47 ca ses of lumbar disc protrusion,
were of the
opinion that there was no relationship between facet a symmetry and intervertebral disc prot rusi o n . At the
thoracolumbar junction, the v ar iabi lity in zygapophy
Vertebral degenerative changes
sial joint orientation was not shown to influence the d egenerative
There is lim ited literature on clegene ra ti v e changes of the
vertebrae
of
the
cervicothora c i c
junctional
p a tter n s ,
on
of the zygapophys i al jOints of the ver tebral column
orientation
and reported an increased incidence of disease in the
remains inconclusive.
cervicothoracic junction - a flilding he termed t he peak.
Shore
s pecul ated
that
the
histologically,
of
recorded for the cervicothora cic junction the debate
region. Shore (I935) consiclered osteoa rthri t is (OA)
cervicodorsal
recorded
these joints (Sin ger et al., 1990a). With no da ta as yet the relationship between anel
vertebral
zygo p op h ysial
d egenerative
joi n t
p atter ns
In addition, the ana lysi s of assoc ia tion between zygapophysial joint degeneration a nd zygapophysial
ex p lanation for this flilding may lie in the al t era t i on of
jOint asymmetry must be a ppro a che d
the col umn in ord er to maintain the p O Sition of the
degree
head in the upright posture on a changing thoracic
normative dara on aged zyg a po ph ysi a l joint appear
of
caut ion .
There
appear
to
with some be
limited
kyphosis. The cha ng e in direction (infl exio n ) of curve
ance and in par tic ul a r what constitutes degenerated
coup led with different fu nct i onal demands might
j oint appearance. Fletcher et al. (1990), in a small
tend to localize stress on the cervicothoracic zygapo
series of 20 cadavers, demonstrated that the m ajority
ph ys ial joints . Certainly there h as been su p port for an
of
increasin g
normal appearance. They reported that, in cadaveric
thoracic
kyp hosis
in the aged female
cervical
Copyrighted Material
zygapophysiaJ
joints
do
not
have
a
46 Clinical Anatomy and Management of Cervical Spine Pain spe c im en s, 37 years of age or o ld er, ar ticu l a r carti la g e is redu ce d to a thin, d i sco l o ured or mi c ros cop i c lay er and that menisci are non-existent. In contrast, Bland (1994) showed synovial folds (menisci) with cervical facet j oin ts to be a comm o n occurrence across the a ge spa n. Fletcher et at. (1990) ind icated that about h alf of t h e ce rvical j o ints in adults have thickening of subchondral bone or osteophytes, as well as cartilage loss. In pa tic ul a r the lower and mid cervical l eve l s were u s u al ly more seve rely affected. T hese data are supported by Frieden berg and Miller (1963), who reported th a t 25% of th eir asymptomatic patients demonstrated degenerative cha ng es on radiographi c ex a m ination by their ftfth decade and by the se ven t h decade, 75% showed roentgenographic d eg en erativ e changes. S imil a r l y analysis of dege nera tive changes of the intervertebral dis c s must be a p p roache d with some caution. Ten Have and Eulderink (1980) rated cervical discs on the presence or absence of di scal splits. The r
limitation with the Ten H ave and Eulderink (1980) disc a na lys i s is that c lefts may be found in the middle of hea l rhy cervical dis c s on c o ron a l ins pec tio n (Tondury, 1959, 1972; Bland, 1994). These clefts may starr to appear in the uncovertebral j Oint regi on as ea r ly as 9 y ea rs of age. Tondury (1959) and EckJin (1960) both deny t h a t the formation of uncovertebral fissures in the cervical intervertebral d i scs should be regarded as a degenerative process. Of p art i cul a r interest, given the proposed ef fects of the uncovertebral joints in the development of discal clefts, is the influe nce of t h e ribs in theif articulation with the thordcic discs. luschka (1858) suggested that th e tUlci ll ate pro ce sses are hom ologou s with the rib h eads This postulation has gained some support in the literature (Bull , been specul ated t h at the contact of th e rib head with the fibroc art i lag e of the a n ulu s may prod uce the same kind of changes as seen in u nco v e rtebra l joints (Milne, 1993). F igu re 3.6 demonstrates the similarity between
,
.
,
Fig. 3.6
Coronal
sections through the
(A)
cervical
and
(B)
upper thoracic human spine
demonstrating carbon particles in the uncovertebral j oin t s ami the costovertebral joint of
the
second rib (arrows) foUowing injection of suspended carbon into the centre of the intervertebral discs.
The
migration of carbon within these joints demonstrates fissures within
communication with the costovertebral
and
ullcovertebral joints.
Copyrighted Material
the disc tissue and
Clinical anatomy of the cervicothoracic junction 4 7
the uncovertebral and costovertebral joints wi th leakage of radiopaque dye from upper thoracic discograms into the costovertebral joints. Given the scarcity of litel�lture on degenerative patterns of the intervertebral disc through the cervicothoracic transition, 96 vertebral columns from the sixth cervical to the fourth thoracic vertebra were studied (Boyle et at. , 1997). The disc-grading scale of Ten Have and Eulderink (1980) was used, com plemented by the categories of discal changes of Nachemson (1960) which has previously been used to rate lumbar discs. Comparison with other studies was limited to previous cervical investigations. How ever, data from this study compared favourably with the ftndings of Ten Have anet Eulderink (1980). Analysis of these cases revealed that there was a decline in the incidence of degenerative changes in the intervertebral discs from the C6-7 to the T1-2 segments. However, there was increased incidence recorded at the T2 -3 segment and comparable results at the segment below, which was more consistent with the lower cervical findings (Fig. 3.7). This increaSing incidence is surprising given the presumed stabilizing effect of the thoracic cage and increased stiffness of the thoracic spine (Panjabi et at. , 1976). The high frequency of degenerative findings in the mid cervical spine is well-documented (Fletcher et al. , 1990; Milne, 1991). This finding relates to the combination of disc-facet and interfacet angles seen in the mid cervical vertebrae which allows for larger anteroposterior translation during sagittal motion and a greater freedom in combined lateral flexion and axial rotation (Milne, 1991; Milne, 1993a,b; Fig. 3.5).
This pattern of movement is thought to result in greater shearing forces in the intervertebral discs (Tondury, 1959). The variations in orientation of the zygapophysial joints through the cervicothoracic transition may in part account for the discal degenera tion in the upper thoracic spine. Unfortunately a causal link between the angular asymmetries and the pattern of discal degeneration in the cervicothoracic junctional region could not be measured in our study (Boyle et al. , 1997) due to prior autopsy procedures rendering measurement of zygapophysial configura tion impossible. In inspecting degenerative changes in the cervico thoracic transition, significant trends with respect to age were identified (Boyle et aI. , 1997), consistent with the view that there is an increasing frequency of degenerative lesions with ageing of the human spine. In the youngest age group 0 1 - 29 years), 75% of a ll discs were graded normal, with the majority of the remainder demonstrating minor lesions. Ratings of normal declined steadily through the age categories, with the 30-49-year group recording 62% of all discs as havi.ng no degenerative lesions and the 50-69-year group scoring 57%. In the oldest age group (greater than 70 years), only 42% of all discs were graded normal anc!, of the remainder, over half were moder ately to severely degenerated. The frequency of osteophytic lipping decreased dramatically from the C6-7 vertebral segment and thereafter remained constant in frequency into the LIpper thoracic region (Boyle et at. , 1997). The lowest incidence of marginal vertebral osteophyte formation occurred at the C7 T 1 vertebral segment. The report -
Segmenta l patterns of degenerative chan ges C6-C7 C7-T1 T1 -T2 T2-T3 T3-T4 10
o
Disc degeneration (Ten Have) (Nachemson)
End-plate lesions
Osteophytes
Fig. 3.7 G ra ph i c a l s u m m ary o f til e incidence of degenera tive changes for tile vertebra l segments of the transition from sagittal m i d l ine inspectio n of 96 verte b ra l columns, b a s e d o n t w o rep orted scales of d i scal dege n e ra t i on (Nacll e m s o n , 1 960; Ten Have and Eulderi n k , 1 980) . Patterns of end-plate lesions and ourgi n al osteophyte formation are a l so presente d . In generdl, t h e last cervical (mobile) segme n t tends to be affected most. Modified from Boy l e et at. ( 1 997).
Copyrighted Material
48 Clinical A natomy and Management of Cervical Spine Pain by Natha n
( 1 962)
sh o wed a similar trend, suggesting
t ra n S I t i o n
f rom a very mobil e cel-vica l spine to th e
th a t Tl and T2 were least l i ke ly to d e velop an ter i o r
re l a ti vel y rigi d thoracic s p i n e . Ro g er s et at ( 1 980) ,
ve rte b ra l body os t eophytes in the w h o l e ve rtebra l
rev i e w ing 35 cases of upper thoracic s p inal trauma,
column. I n co ntrast, Nathan added t h a t
C 6 had
the
searched fo r pattern s of r e s ul tan t booy lesio n s . They
hi gh e st freq u e ncy of osteop h yt e fo rmation in the
report e d a b a s ic p a t tern of i n j u ry occu rri ng in 2 2
c e rv i c a l sp i n e . The com pa rison of d iscal degenera t i ve
c a ses
changes , as d e fin ed by N a che m so n ' s grading, with the
vertebra e
inc idence of os teop hyt e presen c e , i ndicates that if the
a n te riorl y. Ad d i tion a lly, associated s e c o n d a ry spin a l
with
a
fra c tu r e
wi th
i n vo lvi ng
s up e r i o r
the
two
verte b rae
con t iguo u s d islocated
not
inj u rie s w e r e conun o n ( 1 7% i n cid e n c e ) a nd lI s u a lly
c o mmo n . H owever, in t hi s series o f 96 cases, one-third
represented a hyperexte n s i o n in j u ry of the u pp e r
of the
cervi c a l sp in e .
d i sc
is
normal
then o steo ph yt e fo r m a ti o n
d ege n e ra ted
is
inte rvertebral d i scs were not
associated with evid e n c e of os teo p hyte formation on s a g i tt al mi dl i ne in sp ect i o n .
Dislocation or fra ct u r e d islocation at the C7- T l
l evel s i s a rare i n j ury. Eva n s ( 1 983) re p o rted 1 4 cases
The rel a tionship be tw ee n the presence of ce rvica l
fro m 27 yea rs of s p in al i nj u ry m a n a ge ment at his
of
centre, o u t of a s e r i es of 587 cel-vical t ra u m as. A s i m i l a r
symp toms was studied by Frie d e nberg a n d M iller
th e incidence o f cha nges a t t h e po sterola te ra l m argin s
inci dence rate is rep o r t e d by All en et al. ( 1 982), who record ed 1 0 ca se s from 1 6 5 lower ce rvi ca l inj u ries over 1 5 years. In a n o ngoing review o f spinal inj u r cases from the S ir Geo rge Bed b rook S p i n a l Unit at t h e Roy a l Perth R e h a b W t a t ion H o s p i tal , Western Aust ral ia (Bo y l e , u n p u blis h ed ) 6 ca ses have b e e n identifi e d .
of t h e vertebra l bodies, t h e in te rverte b ra l fo ramina o r
T h i s series rep rese n ts a n l l -yea r re view ( 1 98 5 - 1 995)
degenera tive
lesions
and
p a tie nts '
co m p la in ts
( 1 963) in 1 60 asymptomatic patients and compared 92 of them to age- a n d gender-ma tched p a t ients w i t h cel-vical pain . Us ing ra d iogra p hi c e x am i nat i o n t h ey reported no d iffe re n c e between these two groups i n
y
,
t h e zygap ophys i a l j o ints . T h e associati o n , by these
out of a to tal of 865 spinal i nj u r y cases. Five of the 6
authors, betwe e n postmortem observations and clin
cases reflect the basic pa t t e r n d escribed by Ro ge rs et
i c a l p ain syn d ro m e s w a s co n s ide re d te n uous .
al. ( 1 980) , and w o u l d be c l a s s ifi e d u n d e r the dis tractive-flexion category ( A ll e n et aI. , 1 98 2 ; Fig. 3 . 8) , a l though
a ro ta r y component a p pears to b e an
a dd i tio na l fe atures i n two cases. The final ca se is
Spinal trauma
co n sis t en t with the vertical compression category Ll s i ng th i s c l a ssifica tion (re p rese n ted in F i g . 3 . 9) .
Transiti o n a l regions of the h u man sp i n a l column a re
There a p pea rs t o be gen e ral
consensus i n t h e
considered to be vu lnera ble to inj u ry d ue to the
litera tu re t h a t , a l th o ugh these l e s i o n s are u ncommon,
a br u p t changes in vertebral morphol ogy wh ich alter
they are easily m i ssed and cl oser s cr u t i n y is re q u i red
sp inal mechan ics and load tr'd. nsmission (Kaza r ia n ,
when ex a m i n i n g tra u m a i n th is reg i o n , Eva ns ( 1 983)
1 98 1 ) . The biomecha n ics o f the cervicothoracic j u nc t ion a re co n s id ered so mewha t u ni qu e d u e to the
re p orted that nea rly two-third s o f all cases reviewed were not pro p e rl y d iag n o s ed Oll a d mi ss ion and that
Mecha n i s m s of cerv i c ot h o rac i c j u n ct i o n t ra u m a
Fig. 3.8 The
ty pical
mech a n i s m s o f i n j ury resulting i n
cervicothoracic j u n c t i o n i s extreme flexi on (A).
rotation, fractures .
without
frac ture - dislocations a t
B shows axial
the
c o m p ression with o r
Hyperexten s i o n (C) c a n res u l t i n posterior j o i n t complex compress i o n
Copyrighted Material
Clin ical anatomy of the cervicothoracic junction 49
e lements . In the l a rge p a t i e n t magne tic resonance ,
imaging of the cervicothorac ic ju n c ti o n p rov i d e s a
more detailed i nve stig at i on and is c ons i de red t he
examination of choice if fra ctu re or fracture - disloca tion is sus p ec te d (Ke rslake et at. , 1 9 9 1 ) . An added ad v an t age i s th a t magnetic resonance im a g i n g is also
c ap ab le of demonstrating oedema a nd h a e m o rr h age within the sp i n al c o r d .
C o m pli cat i o n s fo ll o w i ng
acic
region
a re
trauma
to the cervicothor
w i t h An
common,
et al.
( 1 994)
repo rti n g 28 out of 35 c a se s presenting wi t h ne u ro logic al deficits. In t h e 1 4 cases re p o r ted by Eva ns
( 1 983), 1 1 we re associa ted with the spinal cord ,
a
comp lete l e s ion of
all re m ain ed complete. These
a nd
findings m ay in p art , be reflective o f t he decrease in ,
canal size i n the thoracic s pine .
Fracture of the vertebral body of the first thoracic vertebra is very rare and usually involves grea t fo rce . This is though t to reflect the sta b i lizin g effe c t of th e first rib Oones et at. , 1 984). Fracture s of the spinous processes of either C7 o r T l , m o re commonly known shoveller'S fra c t u re s a re
as
t h ough t to
be
stress
fractures due to re pe t i t i ve muscular acti o n . F i r st rib frac t ures can be e i ther anterior or po ste rior with t h e ,
l a t t e r often i n vol v ing the costotldl1sverse a rtic u l a tion a n d the tran sverse p ro ce s ses o f C7 and Tl Oones et
al. , 1 984). The question a rises as to whether the m o rp ho
,
logical v a r i at i o n s evi dent in the transitional regions of
the
s pin e
influence
degenerative c h ange s
the .
patterns
of t raum a
and
In the thoracolu m b a r tra n s i
tional re gio n Singer et at. ( 1 989) compared a series of
630 normal pa t ien t co m pu t ed t om o gra ph i c sca ns scans of 44 p at i e n ts with thoraco l u m b a r
with
in j u ri es
.
Th e y concluded that individ uals with a n
a br up t transition
Fig. 3.9 Tra nsverse p l a n e c o m p u te d tomogra p hic sca n of the cervicoth o ra c i c jun c t i on from an 1 8·yea r,old male in vo l ved i n a rol l over motor veh icle accidem. Scan A demonstra tes a c o mm i n u t e d b u rst fra c t u re of C7 with a lmost c o m p lete ablation of the spin al canal and i n volve ment of the artic ular processes. Scan B demonstrates a cleaved fl�lcture of the body of T I with assoc iated frac tu res of tile left l a m ina and cemral s pinous p roc ess . The neu ro logical lesion resulted in an inc o m p l e t e q u a d r i plegia below C6 and c o m p l ete qua d r i p legia below T I . Th is case i l l ustra tes the vi ol e m n a t u re of cervicothora c i c j u n c tion in j ury.
of thoracol umbar j u n c tion mortice j o i n t s was d e mon·
strated in the inj ury gro u p . There has not been a sintiJar i n vestiga ti on of th e cervico thoracic j u nct i on re p o rt e d .
Clinical anatomy The
with dislocations at the ce rvi cot h o ra ci c j u nc tion re qu i r e
had a greater p re dis p os i t io n to
to r sio n a l inj u ries at t his j un c t i o n . A h i ghe r in cidence
cervico thoracic
the
other
transition
j u nctional
appears
regions
consistent
o f the
spin e .
Marked cha nges in verte b ral morpho logy o c c u r at
carefu l scrutiny. The d iffi c u l ty l i es in the i n a bil i ty of
the
routine l a tera l ra d i ogra phs to id e ntify I.esions unless a
fea t u res of the thoracic regi o n . Changes occur in
' swimmer's p ro j e c t i o n ' technique is us e d (Fig . 3 . 10) .
The
l at e ral X-ray is taken w i th
th e p a tient s a r m '
tran sition
as
the
cervical
sp ine
assumes
the
the o r i enta ti on of the zygap o p h y s i a l j oi n ts t h rough the transition an d the incidence of fac e t trop ism is
elevated above t h e h e a d w i th the oth e r arm pe rpen·
s u c h that care w h e n
dicu l a r to the body. D esp i t e better v i s u a li zation of the
te s t in g of individual segments is necessal-y. Add i t ion
upper thotdcic spi ne
ally, accessory gliding of these segments may test
with this
technique,
tomo
graphy i s con si d e red essen t i a l to reflect the true status
of
the
vertebral
body
and
the
po s terio r
int e rp re ting pas sive m a n u a l
with va riations in ra n ge and quality of movement
i r respect i ve of the presence o f pathology.
Copyrighted Material
G rieve
50 Clinical A natomy and Management oj Cervical Spine Pa in
A
B
Fig. 3. 1 0
Swimmer's view X·ray
(A) , with
associated o u tline
(B),
to il l u strate a b i l a teral d islocation a n d fracture of C7 on
Tl
i n a 26·year·old m a le following a motor vehicle a c c i d e n t .
( 1 994)
rec ommends cau tion, b o t h i n interpreting
apparent treatment
abnormal using
motio n ,
manual
and
in
the rapy
the
at
the
na t u re
References
of
thoraco
Alle n , B. L. , Ferg u s o n ,
D e sp i te
the transitional variations in verte bral morphology, it would be s purious to associate the vari atio ns described here with increased likelihood of changes
in
e i t h e r the
zygapophysial
j o ints or interve rte bral disc. Given the relatively h igh incidence of degenerative disc changes a nd zygapo
An ,
H . S . , G o rd i n ,
R.,
2 5 5 7 - 2564 . the
saginal
cause of p ati en ts ' sympto m s . Based on upper tho
7 1 7 - 72 1 .
racic vertebral body morphology, and the post u lated weight transmission, this region is potentially an area of localized s pinal stress . The upper thoracic s p ine wit h
this
increased
Bla n d , J , H . ( 1 994)
kyphosis could be loo ked upon as fur t h er accentuat
normal thoracic and
Spine 14:
j u n c ti o n .
Disorders of the Cervical Spine ,
2 n d ed n .
P h il ad e lp h i a : S a u n el e rs . Boyle,
HW., S inger, K . P ,
M ilne , N. ( 1 996) Morp holog i c a l
su rvey of the cervicothoracic j un c ti o n a l re g io n
loa d i ng .
Deterioration in posture with an increasing thoracic
of the thoracolumbar
p l a n e align ment
l umbar spines a n d
assist
Spine 7: 1 - 2 7 . K . ( 1 99 1 ) An atomic consid era fi x a t i o n of the cervi c a l spinc. Spine
Bernh ard t, M . , Bridwell, K . H . ( 1 984) Segmen tal a n a lysis of
ribs
A
16: 554 8 - 55 J An, H . S . , Vaccaro, A . , Co tl e r, ) . M . , Un, S. ( 1 994) Spina l disorders at the cervicoth oracic j u nctio n . Spin e 1 9 :
a cic j u nct i o n should not be overlooked as a possible
the
et al. (1 982)
Ren ner,
t i o n s for p l a te screw
p h ys i a l jo int d egenera tio n reported , the cervicotho r
and
Leh m ann , R . R .
dislocations of the lowe r c e rv i ca l spin e .
the cel-vicothoracic j u nctio n .
degenerative
R.L.,
mec h a n istic classi fication of c1osc d , i n d i rect fractures a n d
l u mb a r transi t i o n . The sam e advice is suggested for
5 4 4 - 54 8
Boyle , ] I W. ,
Singe r,
Copyrighted Material
M il n e ,
N.
Spine 21:
( 1 997) I ntervertebral
e1isc
degenera t i o n in the c e rvi c o t h o racic j u n ct i o n a l regio n .
Manual Therapy
ing the stress in this transitional region.
K.P,
.
( i n press) .
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,
a normal female popula t i o n . I n : Manipulative Therapists H . M . , Jones , M . A . , Milde, M . R . , eds) 6: 34 - 4 4 , Adel a i d e , South Au s tralia : MTAA. Ec kl i n , U. ( 1 960) Die A ltersvercmderungen del' Halswirbel Association of A ustra lia Ganes,
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Evans, O . K . ( 1 983) D i slocations at t he c e rvicothoracic j u nction. } Bone jo int Surg. 65-B: 1 24 - 1 2 7 . Farfan, I-I . E , Su l l iva n , J. D. ( 1 967) T h e re l a t ion o f facet orientation to interverte bral d isc fail u re . Ca n. } Surg. 1 0 : 1 79 - 1 8 5
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related changes in the cervical facet joints: studies with cryomicrotomy, MR and C'T. A J R. 1 5 4 : 8 1 7 - 82 0 . Fon , G.T. , P i tt, M.) . , Thies, A . C ( 1 980) ThoraCic kyphosis: ran ge in normal subjects. A J R. 134: 979 - 98 3 . Francis, c . c . ( l 95 5a) Dim e n s ions of the cerv i c a l v e r tebra e . A naL Rec. 1 2 2 : 603 - 609. Francis, C c . ( 1 9 5 5 b) Va riations in the a rti c u l a r facets of t h e cervica l vertebra e . A nat. Rec. 1 22 : 589 - 60 2 . Fra n c is, C . C ( 1 956) Certain changes i n t h e a ge d m a l e wh i t e c e rvical spine. A nat. Ree. 1 2 5 : 783 -787. Friede n berg, Z . B . , Miller, WT ( 1 963) Degenera tive disc disease of t h e cervical spin e . } Bone joint Surg. 4 5 -A : 1 1 7 1 - 1 1 78 . Gilad, I., N issan , M . ( 1 986) A study of vertebra a n d disc geom e t ric re lations of th e h u m a n cervi c a l and l u mbar s p i ne. Spine 1 1 : 1 54 - 1 5 7 Giles, l.G E ( 1 987) Lu m bo-sacra l zygapophyseal j O in t tro pism a nd its effect on hyaline ca r til age . Clin. Bio mechanics 2: 2 - 6. G l adstone, R .). , Wa ke ley, c . P G. ( 1 9 3 2) C e r v i c a l ribs a n d rud im en tary fi r s t t h o racic r i bs considered fro m the clinical and etiological stand points . } Anal. 6 6 : 3 3 4 - 370 G riege l - M o r r i s , P, Larso n . K., M uell er-Kl a u s , K . et al. ( 1 992) Incidence of common postural abnormalities i n ' rhe cervica l , shoulder, a n d thoracic regions and thei r associa tion with pain in two age groups of healthy su b jec t s . Phys. Ther. 7 2 : 4 25 - 4 30 . G r i e v e , G. P. ( 1 994) Bony and s o ft tissue a n o m a lies of t h e ve rtebral c o l u mn . In : Grieve 's Modern Manual Therapy: The Vertebml Column, 2 n d edn ( B o yli ng, ] . D. , Pa las t an g a , N . , e d s) . C hu rchj ll LiVin gs t o n e , p p . 240 - 24 1 . Hagg, 0 . , Wa ll ne r A. ( 1 990) Facet join t asymmetry and protrusion of t h e i ntervertebral disc. Spine 1 5 : 3 5 6 - 359 Hall, M . C ( 1 965) Luscbka 's joint. Springfie l d , 1L: T h o m a s . Jefferso n , G . ( 1 927) Discussion o n s p in a l injuries. Proc. R. Soc. Med. 20: 62 5 - 63 7 . J on es , M.D., Edwards, K . C . , O n g , E. (I 984) T h e cervicothor acic j u nction on chest rad iogra p h . Radio/. Clin. North Am. 2 2 : 4 87 - 4 96. Kaza rian , L ( 1 98 1 ) Injuries to the human sp in a l colum n : biomechanics a n d i n j u ry classitlcation . Ex. Sp ts. Sci. Rev. ,
9: 297 - 3 5 2 .
Kersl ake, R . W , Jaspa n , T , Wort h in gto n , B . S . ( 1 99 1 ) M a gnetiC
resonance imaging of s p i n a l tra u m a . Br. ) Radia l. 64: 3 86 - 402
Human P , e d ) . Ned lands, Western Au s t ra l ia : Cen tre for Human Biology, UWA , p p . 1 7 1 - 1 85 . M il ne, N. ( 1 99 1 ) The role of zygapophyseal jo i n t o r i e n tation and uncin a te p rocesses in conrrolling m o ti o n in m e Conference of the A ustmlasian Society for
Biology (O ' H iggins.
.
cervical spine . } A nat. 17 8 : 1 89 - 20 1 M i l n e , N . ( 1 993a) Compamlive artCltomy and function of the uncinate processes of cervical vertehrae in humans and other mammals. Ph D thesis , Universiry of We st e r n Aus tralia .
Mil n e ,
N. ( 1 99 3 b) Composite motion in cervical Ctin. Biomechanics 8 : 1 93 - 20 2 .
disc
segmen t s .
Nachemson, A . ( 1 960) Lumbar intradiscal press ure. Acta Orthop. Scand. Suppl. 4 3 : 2 5 - 1 04 . Nath a n , H . ( \ 962) Osteophyte, o f the ve rt e bra l co lumn . An a n a to m i c al study of t h e i r development according to age, race and sex with c o n s ideratio n s as to thell' e t io logy a n d s i gnifi canc e . } Bone jo int Surg. 44·A: 2 4 3 - 268. Oegema, T. R . , Bradford, D.S. ( 1 99 1 ) Th e inter-relationship of facet j o in t osteoa rth ritis and degenerative disc di se as e . Br. ) Rheumatol. 30: 1 6 - 20 . Ove rto n , L. M . , G ro s s m a n , ].W ( 1 9 5 2 ) Anatomical variation in the a rti c u l a t i o ns between the second and third ce rvical ve r te bra e . } Bone joint Surg. 34-A: 1 5 5 - 1 6 1 . Pal, G. P , Routa l , R . V ( 1 986) A study of weight tra n smission through the cervical a nd u pp e r thoracic regions of the ve r te b ra l column in m a n. } A nat. 148: 245 - 26 1 . Panj a b i , M . M . , B ra n d , R . A . , White, A . A . ( 1 976) Mechani c a l p roperties of t h e h u m a n thoracic s p ine . } Bone JOin t Surg. 5 8 - A : 64 2 - 6 5 2 . Pa n j a b i , M . M . , Durancea u , ]. , Goel , V et Ci t. ( 1 99 1 a) Cervic a l human vertebra e . Quantitative three-d imensional ana tomy of the m i d d l e a n d l ower regions. Spine 1 6 : 86 1 - 869. Pa nja b i , M . M . , Ta kata, K., Goel, V et a l. ( 1 99 1 b) Thoracic h uman vertebra e . Q u a n ti tat ive three-dimensional ana tomy. Spine 1 6 : 888 - 90 1 . Penning, L. ( 1 988) Differences in a n a t o my, m otion, develop ment and ageing of the upper and l owe r cervical disc se gm en ts . Clin. Biomechanics 3: 3 7 - 4 7 . Penning, L . , Wilmink, ] . T ( 1 987) Rotation of t h e cerv i c a l sp ine . Spine 1 2 : 7 3 2 - 73 8 Rogers, L. E , Thayer, C , Wei n be rg , P E . et ai. ( 1 980) Acute
Copyrighted Material
52
Clinical A natomy and Management oj Cervical Spine Pain
inj u r i e s o f the u p p e r thoracic
s p in e
1 3 4 : 67 - 7 3 . Jungha n n s , H . ( 1 97 1 ) The
asso c i a t e d wi t h
Sta nesc u ,
Sch mori, G . ,
Healt}]
S.,
Ebrahei m ,
N.A.,
Yeasting,
R.
et al.
( 1 994)
M o r p h o m etric e v a l u a t i o n of the c e rvico-t horacic j unc
p a raplegi a . A J R.
tio n . Practica I considera t i ons of poste rior fIXation of t h e
Human Spine in
1 9 : 208 2 - 2088.
edn (Be se m a n n , E . F , tran s )
( 1. 997) B i o m e c h a nics of t h e
The
B. et al. ( 1 988) Vertebral morp h ol ogy: s p i ne
Shore,
the
normal
1 08 2 - 1 086.
L.R.
vertebral
Twomey,
I f.A. M.]. ,
8 3 3 - 849
K . P ( 1 996) C lin i c a l a na t o my of t h e t h oracol u m bar j u nc t i o n . In : Clin ical A n atomy and Management of Low Back Pai n (Gil e s , L. G. E . , Singer, K . P. . eds) . Oxfo rd : B u t terworth-H e i ne m an n ( in press) . Singer, K.l� , Will e n, ]., B re i d a hl , P o. el al. ( 1 989) R a d i ologic study of the infl uence of zygapophyse a l joint orientation
t h o ra c ol u m bar of radiograp il i c r h o ra c i c
KP,
Pric e ,
Pa th ot. 1 32 ] ) 3 - 1 '>9 (J 9 5 9) I..;, colollne cervicale: son deve l o p pe ses mod ifi c a ti o n s d u rant la v i e . A cta Orthop.
mobil i ty. ] ment e t
Belg. 2 5 : 602 - 6 27 Tbndu ry, G . ( 1 972) T h e
b e h a v i o u r o f t h e cervical d iscs
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c.,
Zotterma n ,
Y,
eds) . Pergamon Press, p p . 5 9 - 66 . R . E . ( I 990a) I nflu e n c e o f
Ve iea n ll .
C ( 1 97 1 )
o n h y a l i n e c a rtilage a t
f M PT 1 3 : 2 0 7 - 2 1 4 . P D. ( l 990b) A c o m p a rison
Day,
R.E.,
Breida lll , and
"f;n likance . A cta Anat. PD .
U1 nn n .
lumbar
v e r t e b ra l body compressive s t re n g t h : c o r re l a ti o n s w i t h b o n e min e ra l d e n s i ry a n d vertebral regio n . B o n e
D i a conesc u ,
82: 97( 1 969) Ana l ysis o f the m e c h a n ic s
c u rv a t u re .
of t h o ra c i c
U"
G rii n ,
pec u l iarities o f t h e thoracic
con' p Uf c r-assisred measu re m e n ts sagi t t a l
Ver t e b ra l stru c t u r a l pecu l a r i ti e s w i t h a
c e rvical spin e mech a n ic s
Radial. S inger,
F
Tond b u ry, G .
Radiol. A nal.
Singer, K P .
E u l d e ri n k ,
c h a n ges in t h e cervica l spine a n d t h e lr re l a tionsh i p to its
on spinal i njuries a t t h e t h o ra c o l u m b a r j u nctio n . Surg.
zygap o p l ly,r a l
L.T ( 1 98 4 ) SeXII111
, {' ncbral body s h a pe . ] A nal.
m orbid a n a t o my. Br.] Surg.
S i nger.
S i n ger,
K. P. ,
B l l t t e rw o r t h -H e i n e m a n n (in
O,[(o·"rthritis in rhe dorsal in te r
1 1 : 2 3 3 - 23 9 . K P . G il e s . L . G . F , D ay.
Clinical A natomy
Spine Pain (Singer,
An
experim e n ta l study
Samcl. Suppl. 1 2 7 M . M . ( 1 990) K i n e m a t ic s
01·thop. Wh i t e ,
17:
1 67 - 1 74 .
In:
A.A.,
Pa nja b i ,
Clinical
Biomechan ics
P h il a d el p h i a : Li p p i n c o t t
Copyrighted Material
of the
of the spi ne.
Spine,
2nd
edn.
Normal kinematics of the cervical spine 1. Penning
This ch apter deals with a radio l ogi ca l analysis of normal motion of the cervical spin e followed by a functional anatomical correlation.
Functional radiographic studies Kinematics is the study of motion without taking into accowH the influences of force and mass (as opposed to kinetics). Spinal kinema tics have been profoundly studied by radiological methods. This chapter deals with the radiological analysis of normal motion of the cervical spin e, followed by a comparative review which relates the anatomy with function. Motion takes place in the separate motion seg ments of the craniovertebral junction, oc ci put to C2 (occipitoatlantal segment occiput-Cl, atlantoaxial segment Cl-2), and of the cervical spine proper C2 -Tl, in cluding the cervicothoracic junction C7-T1. Only movements in the three main pl ane s are described: flexion -extension in the sagi tta l p lane; lateral bending to the right and left in the frontal plane; and rotation to the right and left in the transverse (or axial) plane. The head may also move parallel to itself, which is called translation (White and Panjabi, 1978; Penning 1992a). Such translatory head motion is virtuaUy limited to the sagittal plane. The range of flexion-extension motion is deter mined by superimposition of radiograp hs of the cervical spine in both end-positions (Penning, 1968, 1978). Details are gi ven in Figure 4.1. In super imposition both the outlines of the vertebral bodies and the spinous processes should match. Only these midLine structures may be used as landmarks, not, for
,
Fig. 4.1 Determination of vertebrae.
Flexion
mm
is
ranges taped
of motion (shaded
between
area)
to
the
viewing box (occipital and vertebral outlines OCCiput to in
solid
lines).
C7
Part of the outline of the mm edges is
shown. To determine flexion-extension range of motion of, e.g. C4 - 5, an extension view and
film
edges
shown
imposed on a flexion
film
in
ftlm
(vertebral outlines
interrupted
lines)
is
super
with the images of C5 matching.
Then a line is drawn along one edge of the extension film on the underlying flexion images of
c4
fi.lm
and
viewing
box.
Next,
are made to match and a new line is drawn
along the corresponding edge of the
extension mm.
The
angle between both lines is the range of flexion-extension motion at C4 - 5 .
Copyrighted Material
54 Clinical Anatomy and Management of Cervical Spine Pain Vortman (1992), the a verage difference in each segment is 1.5°. Ranges show wide variations (Buetti Bauml, 1954; D vora k et at., 1988; Penning, 1968). When only end-positions are taken into considera tion, sequence of contribution of different regions of the cervical spine to total flexion -extension motion remains unknown. Such sequence can be studied by cineradiography, but small size and poor definition of individual frames interfere with detailed analysis. Using larger frames (100 X 100 mm) and lower speed (4 images/s), Van M am eren et at. ( 1 990) were able to show that motion commences and ends' in the lower part of the cervical spine (and ne ver in the mid cervical part), and that sequences of c o n t rib ution in normal s u bj ec t s are rather constant. During motion of the c ervica l sp ine as a whole, individual segments may temporarily move in oppo site direction (so-called paradox motion, or inver-
example, the articular processes. Both images should have the same radiological enlargement factor. Differ ences in lateral projection (due to concomitant rotation and/or lateral bending) i nterfere with reliable superimposition and enhance measurement error. If radiographs are too dark to allow reliable super impO Sitio n the contours of vertebral bodies and SpinOliS processes on one ftlm are redrawn on a tra nspare nt paper, which is subsequently super imposed on the other ftlm; this likewise enhan ces measurement error. Ranges of flexion - extension motion are listed in Tab les 4.1-4.3. Range of motion in children is larger than in adults (Mar kusk e 1971). In adults ranges decrease with increasing age, except at C6- 7 (Vort man, 1992). Average range of motion is larger in passive motion (brought about by investigator) than in active motion (Dvorak et at., 1988). According to ,
,
Table 4.1
Ranges offlexion - exte ns ion
A
motion
(in degrees) according to several authors
D
C
B
Occiput-C1 12 (5-20) 10 (5-15)
15 (8-22) 12 (6-[7)
IS (7-2» [9 (13 -26) 2003-28)
17 (10-24) 2[ (14-28) 23 (16-31)
19 (11-26)
21 (13-29)
Cl-2
C2-3
5-18 13-2) 16-28
C3-4 C4-5 C5-6
5 16 13-26 15-29 16-29 6-25 -
18-28 1 3 25
C6-7
-
=
13-42 years, spread of ranges. 15 3 0 years, spr� ad of ranges. Dvorak el al. (1988): n = 28; 22-47 years, aClive motion, average Same gmllp as C, passive motion, average range (± 2 X s.d.). Iluetti-Ilauml
(1954):
D
=
.�- 31
7-26
8-27
9-16 11-23
12-22
15-26 17-27
14-25 18-26
9-2:,\
7-23
10-16
n = 30;
B = Penning (1960): n = 20; C =
- [0-30
4- [2
C7-TJ A
F
n
-
range
(±
2 X s.d.).
E
= Van Mameren el al. (1990): n = 10; 19-221'ears, spread of ranges, extension ---7 flexion: negative values occipllt-CI inuicate par,l......
- -- Head
4
............ Shoulder ---
3
/"\
Seat
§
I r '\.. I' i'
,/
1/. I,:'
I
\
. ••
•
.,,,( .\ '
2
\�'.
:
\
dl
I' .-
�. .
.
'Ii
I. :'
'/ :' //, ./ "
(ms)
Time
Fig.
7.20 Upper-body-neck deformations from rear-end collisions. From the effecr of a linear force [he rear, the shoulder, head and neck deform at different rimes measured in milliseconds. The major forces (g) arc expended within the time under 0.5 s. From Caillier (1995) with from
perOll,";"'lI(Jll
1. Collars
(immobilization):
soft
collars
do
not
restrict the range of motion of the ce rvical s pine
stmlJes, it must be stated, reg a rded cervical pain without objective radicular changes.
yet may promote inact ivity and delay recovery.
2. R est : cumulative evidence suggests that p rolonged uctrimental to per i ods of re,,[ Manipulation:
equivalent
immediate
(less
be
undertaken
pro
mu scl e
week s ,
contractions are
combination with activating inter
-
immobili zation with a moul d e u onhosis for
than
min) imp rovemen t in pain anel
MobiIization
In the presence of nerve root impairment, more aggressive treatment must
su bj ectively
beneficial, is accc [l tai ) ic . Manipulatio[1�
mon-
ventions appear to be beneficial in the short term
itored with re p eated neurolo gical exalrunations. may
but lo ng-te rm benefit remains to be established. 5. Exercise : cumulative evidence s uggests that active
be valuable. Gradual isometric exercises, g ra du ati n g
exercise may be beneficial in the short and long
Ergonomic evaluation and correction of daily activ-
to
are a valid part
term. Traction: there
Ch apter 5 is de voted on the neck
benefi t
[l:l in.
regarding range --r
isokinetic exercises,
Passive modalities, posture trainin g an d electrical
an import ant and
should then be initiated
re habilitation the effect brain as thi�
injury is
cause of llluch suffering .
the rapy remain unproven.
8. Epidural or intr'.lthecal steroid injecti ons are of unproven long-term value. that tim(�. medication and rernedial and all
activities modalities
References use of
living are placebo. Their
Copyrighted Material
C, Bogduk 7.)'1-::1poph)'seal jOUlI 747.
The
prevlti,,"u'
flfst approxl!11111
cervical
Spine 17:
Medical management of neck pain of mechanical origin 1 25 Ap ril l ,
seal
C,
Dwyer, A , Bogd u k , N. ( 1 990) Cervical zygapophy· J o i n t p a i n patterns. n. A clin i c a l evaluati o n . Spine 1 5 :
458-46 1 . Barnsley, L . , Lord ,
5.,
of wrupl a s h . Spin e
Bogd u k ,
N. ,
Marslan d ,
j oints a s a s o u rc e BOLII'd i l l o n , J , E
G r i eve,
G,P' ( 1 98 1 )
cervical zygapophysial j o i n t
7: 2 3 9 - 3 5 3 .
1 4 8 : 233 - 236.
A t l a n to ·a x o i d inst:l b i l i lY, Surg.
zygapophysial
610-617, 3 rd
ed n .
edn.
Phil-
1 390 . l a . , R ya n , M, ( 1 989) Th ,
London : H e i n e m a llfl Ca i l l ie t ,
R. ( 1 9 9 1 )
m anageme n t of a c u t e neck 3 rd
a d e l p h i a : EA. DaVIS.
Cailliet, R ( 1 99 5 ) Soft Tissue Pain and Disability, 3 rcl e d n . P h i l a d e l p h ia EA. Davi s , C a i l l iet, R ( 1 9 9 4 a) Pain: Mechanisms a n d lvlanagement, 1 st e d n , Philadelph i a : F.A. D a v i s . CalLi icr, R ( l 994b) Ne rve c o n trol o f t h e hand. In: Hand Pain and fmpairmenl, 4 t h e cl n (Ca i l l i e r , R , ed ) , P h i l a d e l p h i a : F A . Davis, Pl'. 69 - 1 3 1 . Cle m e ns , H j , Bu row, K , ( 1 972) Exp e ri men ta l investigation o f i n j u r y mech a n i s m s fron ta l veh i c l e i m p"ch
STAPP Car
Crasb
accidents.
27-33. Mai gn e , R . ( 1 972) Douleurs R, ( 1 973)
Lo ndo n : Buttelwort h . M ealy,
K"
B re nn a n ,
H ..
Fenelon,
wh i p i :" h
or the Sixteenth
Springfi e l d ,
Vertebral Man ipulation,
M a i t l a nd , G . D . ( 1 977)
rro n L� 1 a n d rea r-
G . c . ( 1 986) Early 8r. Med.
IL:
4 t h edn, roobiJiza
i n j u r ies,
Shira lmra ,
K . ( J 993) Sp in e 18: 2 1 82 - 2 1 90 . \i. L , Sa Lm i , LR. e t at.
W" r re n d aie : Society of
of
I.
12: 1 97 - 2 0 5 A , Apri l l , C , Bogd uk, N, ( 1 990) Ce rvica l zygapop hy seal j o i n t p a t t e r n s , I. A c l inical eva l u a t io n , Spine 1 5 : 57 4 5 3 -4
Vertebrate et Traite Paris: Exp an s i o n
edn .
Orthopedic Medicine,
Charles C. T h o m a s ,
CTfu n c t i o n a l d iagnoc;ticc; SjJine
2nd
Emerg
S c i e n tific , Maigne,
Dvora k , j, Pa n j a b i ,
D wye r,
A rch,
d 'Origine
ments par Manipulation,
Auto m o t i ve Enginn'ls,
cervica l spine.
Problems,
\1:trsian d , A. ( 1 988) T h e a c c llracy
Ju l l , pathophysiology
( 1 91-);,»
Vertebral Joint
Common
Ed i n bu rgh : Ch u rc h ill Livi ngsto ne .
the
Quebec
d isorders, Spine
Stodd a r d ,
Ma n ual of
Lo n d o n : Hutchinso n ,
task
fonT
20: 8 5 - 7 3 S
OsteojJathic Teclmitlll�
Tayl o r, J R . , Fin c h , P. M . ( 1 993) Neck sprain . A us!. Fam. Phys,
22: 1 62 3 - 1 629,
Copyrighted Material
Surgical nlanagement of neck jJain �r mechanical origin N.
Axial pain
Introduction
This is almost al ways present to some degree and the Mechanical neck
ex tr emely
patholog )
but o nly
surgical intervention .. The less c omrnon ca uses
:Ire more likelv
t u mou r s
,
respond to
ar thri
such as
muscle s
,
all contribute The resul tant
·
specific, but
than the
single most i m portan t c ause, dege nerative disease. The usual indications for surge ry in
debatable.
zygapo pl1ysia l l oints l i gament,
f ai rly
co mmonly
on one
side and tends to involve the muscles. This is often
degenerative
desc ribed as an ache in the shoulder, ra di ating to the
cervical spondylosis are ncrve root or spi n al cord
in tersc apular area and often to the head, leading to
involvement rather than neck pain.
tensio n type headaches. The diffuse nature of this
Recent advanccs significal1l
enablmg immediate
-
spinal instrmnclltJrion have on cervical
surgery,
fIXation,
without
the requirement for external orthoses, but as yet
cervical
it from an
will usuaUy pain blll
absence always easy.
abnormalities this
Axial pai n that is worse at nigh t , espec i ally in an
this has not translated into an improvement in the
elde rly
surgical treatment of neck pain due to degenerative
u nd er l ying malign ancy.
pati ent
,
should
arouse
suspicions
of
an
disease. T hh c hapter
,Ind selec-
pa tients
surg ic al
availahle.
Radicular pain Cervical radicular pain is often equa ted with arm pain, and alt hough this is usu all y the case, not aU cervical radi cu l a r pain is felt in the arm and not all
History
arm pa i n is radicular i n nature. Diffuse arm pain
Presenting
be caused
as a Pancoa � l reflex
The history is often �kewed by medic olegal concerns
when pain follows a motor vehicle accident or work i njur y hut it rema ins of paramount importance. The ,
I umour
dystrophy,
conditions and
diverse
in
of the Joint or
is often a co rnponcnt of a
functional problem. True rad icul ar arm pain is due to cerv i cal
irritation or
pain may be either axial or radicular and in many
compression of
cases there are elements of both. From a surgeon's
commonly affected lIre C(l, C7 and C5. aU of which
of view it
!":I d i cular
that is
a
nerve root. The
and fourth
useful in
neck pain
plac e of surgery
in
Copyrighted Material
s p ondylo ...,i...,
most
nerve rarely eighth
Surgical management of neck pain of mechanical origin 127 Table 8.1 S(�ns of cen'ieal radiculojJatiJy
at one level with little or no ev idence of generalized spondylosis
Nerve rool
Motor signs
deltoid
Shoulder abduction EI bow flexion
None
Elbow extension
Triceps
with mechanical neck pain is rheumatoid arthritis.
Finger flexion and extension Hand intrinsics
Finger
This chronic infl a mmat or y d is order has a p re d iJ ec
Over
C5 C6
Thumb and index
fingers IYUddie finger Fourth and fifth fingers AxiUa
C7 C8 TI
suggesting that previOUS traum a may
,
have been relevant.
SenSOJ]l loss
Reflex
Other medical conditions
Biceps
One of the most imp o rtant conditions associated
Horner's
tion for the upper cen'ical spine , part i cu l arly the atlantoaxial level. Atlantoaxial su b lux a ti o n is found in a lm ost 50% of rheumatoid patients at postmortem (Lipson, 1984). Ankylosing spon dylit is and osteoporo siS are also important general medical proble m s to be A full history and systems review may
cervical nerve root is a lso only rarely affected but
cons idered
does produce arm symptoms.
reveal symptoms consistent with other sig n itlcant
Radicular pain is felt in a my otoma l as well as a
.
underlying conditions, particularly
malignancy. An
dermatomal distribution. Often the p a in is maximal in
elderly person presenting for the first time with neck
the myotome with p a raesthes i a e in the dermatom e . A
pain sh o uld be assumed to have metastatic disease
C5 ra dic ulop athy prod uces pain in the shoulder and
until proven otherwise (Fig. 8.1).
in the deltoid muscle. Compression of C6 causes pain which rad iates into the b iceps muscle and in to the thumb anel index tlnger; C7 pa in involves the triceps muscle and the mi dd le finger, and C8 involves the medial aspect of the fo re ar m anel the fifth fUlger
Examination
(Table 8.1).
General physical examination
\Myelopathy � evere
A c omplete general phy sical examination is imp or tant in the assessmen t of the patient presenting with
·
degenerative
there
disease
may
be
neck pain. One should look for signs of conditions
compression of the sp inal cord from osteophyte s or
wi th a kn own association with neck pain, such as
disc material. The pain associated with myelop athy is
oste oarthrit i s or rhe u matoid arthritis. Signs of wei gh t
usuaUy
more
chronic
and
less
severe
than that
loss, organomegaly or lymphadenopathy s hould make
associated with radiculopathy. Cervical myel opathy
one suspicious of underlying malign an cy.
often causes quite vague sympto m s The spasticiry
with diabetes mellitus are more prone to infections
and weakness it pro duces in the lower limbs may be
and brachial neuritis.
.
reflected in
Patients
mild g a it disturbances, a decrea se in
exerc i se tolerance or frequent tripping due to mild d o rs iflexi o n weakness. U pper cervical cord compres
Cervical spine examination
sion may pro duce the syndrome of' numb, cl umsy
hands', m a n i f es ted by diffuse numbness in the hand s
Inspection
and an inabiliry to perform fine motor tasks, such as do i ng up buttons or picking up coins. Any of these
The patient is observed while at rest during the
symptoms should alert the practitioner to the p ossi
taking of the histor y The range and freedom of neck
b ili ty of spinal cord compromise
movements are noted. The neck is then in s pected
may
,
a
c on dition which
progress rapielly to quadriplegia after
minor
.
after removal of the upper clothing. The webbed neck and low h a irline of KJippel-Feil sy ndrome are indica
trauma or manipulation.
tors
of
an
underlying
abn or maliry
.
Past history
Si m i l arly
,
c onge nital
cervical
the tilted head
and
spine
oc ular
imbalanc e res ulting from atlantoaxial rotatory sub· luxation are obvious.
Most patients with neck pain will be able to recaU some injury, often dating back to childhood faUs or school
sp orting injuries.
It
is
often
difficult
to
Active movement
determine the significance of these compared with the normal effects of day·to·day life. O cc asi onally a
The patie n t is
patient will present with severe degenerative ch anges
l ate raUy flex the neck '''hile attenti o n is paid to t he
,
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a sked to flex, extend
,
rot a te a n d
] 28 Clinical Anatomy ana Management of Cervical Spine Pain
B
A
c Fig. 8.1
(A) A cervical myelogram and
(B)
computed tomogr:aphic scan showing metastases
range of each movement, the rhyth m of the move ment and any apparent discomfort.
from (C)
a
breast
primary.
Passive movement TIle
passive
range
of
neck
m ovements
can
be
assessed but generally adds little to the information already gleaned from active movements.
Palpation
The cervical spin e is palpated gently, starting from the craniocervical
j unction
and progressing caudally,
Other manoeuvres
one segment at a time. It is rare to elicit any sign other
C ompre ssion
than local tenderness. Marked superficial tender ness
cervical spine with consequent wo rsening or allevia
may be an indicator of a funct i onal component to the
tion of nerve root compression symptoms respec
1980).
or
traction
can
be
applied
to
the
is then
tive ly Spurling's manoeuvre inv o l ves hyperextension
palp ated more firmly if the gentle palpation did not
of the neck and rotation away from the p a inful arm.
illness (Wadde ll et aI., any
produce
tenderness.
The
The sp in e muscles
are
then
.
This is sai ci
to
narr ow the intervertebral foramen on
pal pat ed starting with the insertions of the trapeZi us
the side and repro duc e radicular
muscles, which is a c ommon site for focal tenderness. This is cont i nu e d across the shoulder and a long the
L'Hermitte's sign is pain sho ot ing down the legs after flexion of the neck. This is an indicator of either
medial border of the scapula.
cervical spi n al cord compression or demyelination.
,
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arm
pain.
Surgical management of neck pain of mechanical origin 129 Neurological examination
Other
Radiculopathy
A complet e neurological examination may reveal rarer causes of neck pain. Cranial nerve abnor malities may point to a lesion of the skull base or an intrinsic brainstem abnormality. Supratentorial neu rological abnormalities mi ght suggest disseminated malignancy.
Usually the history will have given a strong indica tion of which sign s to t;xpect on examination. Pain, paraesthesiae, numbness or weakness in the dis tribution
of
particular
a
nerve
root
should
be
supp orted by the appropr iate motor and se n sory si gn s
.
panied
Given tim e ,
the weakness wilJ be accom
by was ting and
may even
troph i c
be
fasciculations
in
changes
and
there
the areas
of
numbness. Involvement of C5 will cause weakness of the deltoid and supra sp inatu s muscles whic h abduct
Investigation Blood tests
the shoulder and the infraspi natus whi c h ex ternally Blood
biceps reflex which may be re d u c ed but should still
associated patho l ogy. A raised e rythrocyte sedimen
tests
are
most
in
rotates the shoulder. There is so m e C5 i n pu t to the
useful
the
search
for
be present. Numbness is fo u n d over the upper
tation rate may suggest infection or rheu m atoid
lateral arm.
arthritis; anaemia or hy p erca lcae mi a may be associ
Compress i on of C6 causes weakness of elbow flexion and supin a tion and depression or absence of biceps reflex. Numbness affects the lateral forearm and the thum b and index fmger. A C7 rad ic u lopathy will produce weakness of elbow extension and wrist flexion and extension. The triceps reflex is d ep ressed or absent. The re is sensory loss affecting the middle fin ger and often the posterior forearm. Weakness of finger f lexion and extension and a loss of the finger jerk follow C8 nerve root compression. There is associated numbness in the fifth finger and me dial f o rearm Although Tl lesions are rare, they may imply sinister pathology yet be mistaken for a functional problem. When severe, they will cause weakness of the intrinsic muscles of the hand. A useful sign to look for is a Horner's syndrome, compris ing ptosis, meiosis and anhidrosis, clue to involvement of the sympathetic cha i n There is no accompanying reflex, and sensory loss is in the axilla.
ated with myeloma and elevated prostate-specific antigen with prosta tic carcinoma.
the
,
.
.
Plain radiographs Considerable d iagn ostic information can be glean ed from plain ra d iographs. These should include lateral and anteroposterior projection s
,
as
well as an open
mouth view of the craniocervical junction. Oblique views are sometimes h el pfu l but foraminal stenosis is
much better appreciated with computed tom ogra phy
(CT). If instability is suspected, careful flexion and
extension views can be obtained. In rheumatoid arthritis, particular attention should be paid
Cl- 2 level for atlantoaxial subluxation.
to the
Degenerative changes on pla in radiographs are almost universal and their presence does not neces sarily expla in symptoms. Clinical correlation is of paramount importance. Plain
radiographs may
also detect changes of
rheumatoid arthritiS, metastases, trauma, osteoporo sis and infection. Con genital anomalies such as os
odontoideum and KJ ippel - Feil syn drome will also be
Myelopathy
apparent. Neurological examination of the patient with neck pain is not limited to the upper limbs. If the cord is involved there will be abnormalities at and below the level of involvement. lower motor neuron signs predomin ate at the level of compression and these
CT scan
will be similar to those described under radiculop
CT gives the best detail of the bony structures in the
athy though often bilateral. Below this level there
cervical spine The resolution of the cord is usuall y
will be upper motor neuron signs. The tone is increased and there may be clonus in the knees or ankles. Reflexes are brisk and there may be abnormal reflexes (Hoffmann's s ign in the hand and Babinski'S sign in the foot). The abdominal reflexes are lost in cases of spinal cord compression.
inadequate and shoulder artefacts often obscure the
,
.
lower levels
(C6 7 -
and C7 - Tl). Pa rticularly in thin
individuals at levels above
sufficient to confirm
C6-7, plain CT c an be
diagnosis of disc prolapse or foraminal stenosis (Fig. 8.2), although the degree of a
confidence is usually less than in the lumbar spine .
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130 Clinical Anatomy and Management of Cervical SjAne Pain (MRl), a lthough it is still the best investigation for d e ge ne ra t ive llisease when MRI is unavailable or is not t olera ted by rhe parient. O cca sional l y CT myelography is still used wh en MRl gives equiv ocal
results
and is particularly
useful
when
there are large or widespread osteophytes. In such
cases, the superior bone re s olution of the CT and the
presence
or
absence
of nerve
root
sheath
o pa c ifi cati on with elye can p rov i de strong ev idence for or against nerve root compression (Fig. 8.3).
MRI A MRl has rapidly become the investigation of choice for most problems in the neck. It is non·invasive and
produ c es ima ges of the c ervical spine unobtainable wi th any other modality. Shoulder artefact is not a
probl.em,
cervicothoracic junction. The soft tissues of the neck, the s p in al cord and the nerve roots are seen pa rt i c ul a rly well (Fig. 8.2b). I m ages can be o btain e d in a v ar iety of formats. D isa d vant ages of MRl i n c l u de claustrophobia, wh ich is a common cause of failed exam ina t i on, movement artefacts during the relatively long exam
ination times and me ta l artefacts due to even tiny metallic fragments. Cost and availability also neeel to
be considered.
Nuclear bone scan This is
a
relatively simple i n ves tigati on with reason
able sensitivi ty but poor specificity. It is usually used
B Fig. 8.2 (A) Plain
computed romograph.ic scan showing a
left posterolateral disc prolapse at prolapse demonstrated
with
C5-6. (B) A C6-7
disc
magnetic resonance imaging.
In metastatic disease, the degree of bone destruc· tion will be more obvious than on pl ai n radiogra ph s.
Soft-tissue abnormalities may also be seen and some a pprec iation of the incursion into the spinal canal can
be made. The addition of reconstruction techniqu es, partic ularly with spiral CT scanning, can add considerably to the deflllition and diagnOStic capability of this investigation.
Myelography Myelography with concomitant CT has now been
Fig. 8.3
l a rg ely
oradiculopathy
r epl ace d
by
ma gnet i c
resonance
imaging
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A cervical
myelog(�(m of
a
patient with myel
Surgical management
oj neck pain oj mechanical
origin 131
as a screening test for metastatic disease or i nfection ,
anteriorly. Fusion for degenerative disease is more
but it has largely been supplanted by computer i ze d imagin g techniques.
commonly carried out anteriorly (Fig. 8.4d).
Radiculopathy
This is the most conunon indication for cervical spine
Nerve conduction studies
surgery.
Electromyography and nerve conduction studies are rarely
used
in Australia
for
the
investigation
of
radiculopat hy. Overlap of myotomes and delay in the
development of ch a nges make the results re latively
non-specific in most cases. Some authors advocate examination
electromyographic
of
the
paraspinal
muscles as a way of increasing specifiCity Qohnson
and Melvin, 1971), but the combination of clinical assessment and imag ing is easier and gives superior results.
Treatment
There
is
almost
always
an
element
of
mechanical neck pai n but the arm symptoms and signs are the reasons for surgery. Tn a younger patient it is usually due to an acute disc prol apse but in an
elderly patient the nerve root is
frequently
injured
in
a stenotic foramen, often after a minor injury or repetitive or unusual neck movements (painting the ceiling is a common ante ce dent to such a radiculop athy). Most often, a bout of radic ulopat hy will settle with conservative treatment alone and surgery will
nor be required. The indications for surgery are essentially threefold and are described below. In all c a ses it is imperative that the pain, numbness, weakness and radiological abnormalities are con sistent with each other. There is no point removing a
C7 - T1 disc for a C6 radiculopathy.
Indications for surgery
1. If there is significant neurological compromise in
the
Atlantoaxial instability
In an adult, a gap of greater then 3 mm betwee n the arch of Cl and the odonto i d process is indicative of instability.
Anterior
10-12 mm im plies
subluxation destruction
of
greater
of the entire
mentous complex ( Fielding et al.,
than liga
1974). A gap of
6 mm or more is considered an indication for surgery. In rheumatoid disease, subluxation is often associated with cranial settling. The degree of brainstem com pression arising from this can be determined most effectively with MRI. Unlike subaxial
dege nerative disease,
the most
common indication for surgery at C 1- 2 is neck pain, which is present
in the majority of
rheumatoid
patients with atlantoaxial subl lL"'(a tion (pellici et al.,
1981; Menezes and VanGilder, 1988). A prime con sideration is also prevention of neurological com promise due to progressive slip .
form
of
weakness
or
numbness,
surgical
decomp ressi o n is indicated as a matter of urgency. The definition of significant is relative and the degree of deficit that worries one individual may not concern an o ther. Reflex changes alone are unimportant, other than as an indicator to the affected nerve root. Sensory changes, including paraesthesiae,
vary
in
Significance
with
their
l o cat ion or intenSity. Numbness of the thumb and index finger of the dominant hand is more serious then num bness over the deltoid. The most impor tant neurological deficit is weakness and again the relevance varies with the individual, the particular muscles in volved and the degree of weakness. A glob al weakness is often seen in someone with arm pain and this needs to be distinguished from a true radicular weakness due to nerve root com pression. Reflex changes can help in this regard .
2. If the pain is in the distribution of a nerve root but there
are
no
neurological
signs
and,
despite
conservative treatment, it persists beyond a rea sonable period (usually 6 weeks), surgery may be
Subaxial instability
indicated. This is referred to as irritative brachalgia
This
may be severe in trauma and rheumatoid arthritiS, but in degenerative spondylosis there is usually o nly a relative instability. Loss of disc space
height will allow some movement but significant displacement implies damage to the anulus and/or
facet joints. Some move m ent is normal in flexion
(as opposed to compressive brachalgia, described above, where there is
a
neurological deficit).
3. In cases of irritative brachalgia, surgery may sometimes be in d icated prior to 6 weeks when the pain is severe and unremitting with usual con servative mea s ures .
extension radiographs but this should not exceed
3.5 mm (White et al., 1975). Surgery for rheumatoid subaxial subluxation involves either anterior or pos terior
fusion.
Zygapophysial
joint
IIlJufles
are
usually treated posteriorly and vertebral body injuries
Myelopathy Surgical decompression is almost al ways indicated in cervical myelopathy. This is a slow l y
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p rogressive
132 Clinical A natomy and Management oj Cervical Spine Pain
A
c
B
D
Fig. 8.4 Progressive instability due to degenerative disease. (A) 1988; (B) 1993; (C) 1994; (D) after fusion and t'xatio.n with an anterior plate.
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Surgical management of neck pain of mechanical origin 133 disorder which can usually be st a bi lized by surge ry
unco mmon .
of choice. Su rge ry is indi c a te d ,,,,hen radiotherapy h as
The
failed or if there is bony compre ssion of the spinal
longe r surgery is d elaye d, the gre a ter the long-term
cord. Surgical excision of a single affected vertebral
deficit is likely to be.
body
but
significant
improvement
is
with
fIXation
and
stabilization
will
usual l y
improve pain control significantly. When metastases
Tumour Metastatic tumours are a re latively frequent cause of mechanical insta bility a nd nec k rai.n , often without
are widespread in the spine, su rgery becomes much more difficult and is rarely indicated. Be nign tumours such as sch wannoma are much rarer and cause radicular pain rather than mechanical neck pain (Fig. 8.5).
neurological deficit. They may also cause neck pain without
instabiLity. Treatment depends
to a
large
extent on the clinical state and prognosis of the individual patient. If th e re is no neurological defic it and the spine is stable, radioth erapy is the treatment
Trauma Although acute spinal injury is an important cause of instability and mechanic al neck pain, the indications
A
B Fig_ 8_5 (A) Axial pain.
�nd (13) coronal magnetic resonance images ofa right C2 schwannoma presenting
Copyrighted Material
with neck and occipital
134 Clinical Anatomy and Management of Cervical Spine Pain for surgery are quite controversial and beyond the scope of this chapter.
Smith -Robinson This techniqu e involves excision of the disc and any osteophytes throug h the disc space, usual ly using a disc space spreader to widen the gap. A bone graft is
Non-surgical treatment
taken from the iliac crest and impacted into the disc
A variety of non-surgical treatment options are available for mechanical neck pain and these are covered in grea ter detail elsewhere in this book. In most cases, non surg ical treatment will be the most ap propriate form of treatment, with surgery reserved -
for the minority of patients with the specific indica
tions discussed above.
space to effect a fusion of the level. Some surgeons perform the discectomy but do not fuse the level; this would be considered the exception rather than the rule.
Cloward The Cloward technique involves drilling a circular hole centred on the disc space. This is carried down
Surgical treatment
to the posterior
Cervical spine surgery can be divided into operations done from an anterior approach and those done from a
posterior approach
In many centres there is a
.
historical preference for one over the other but, in general, the spine surgeon s hould be fami.liar with both
and
tailor
the
operation
to
the
individual
circlUnstances.
curettes
and
cortex
punches
.
which
Any
is
removed
osteo phyt es
with
are
also
removed. The posterior longitudinal ligament may also be removed to expose the dura and allow access to any disc fragments that may have penet rated this Ligament. A bone dowel
slightly
larger than the hole
drilled is taken from the iliac crest and impacted into the hole (Fig. 8.6). R a t h e r than autogenous bone, some surgeons use allograft,
xenograft or arti icial f
bone substitutes.
Anterior cervical spine surgery
Corpectomy
C1-2
This is particularly useful when there are degen
(Fig. 8.7)
erative ch ange s causin g spinal cord compression at
The most common indication for anterior surgery at this level is rheumatoid arthritis with cranial settling. Al though this is associated with mechanical neck pain,
the greater concern
is usu ally
neurological
compromise. The odontoid process may be removed transorally to decompress the cervicomedullary junc tion. This is then followed by a po s terior stabilization procedure.
Subaxial cervical spine
Anterior cervical discectomy is a common neuro surgical operation, done for either radiculopathy or myelopathy. The same approach can be used for f-usion
in
trauma
or
vertebral
body
excision
in
tumour. The approach is usually from the right side with a
skin
crease
incision
platysma is divided
at the affected level. The
and the plane medial to the
sternocleidomastoid muscle is entered. The carotid sheath is
retracted
oesophagus
laterally and
medially.
This
leads
the trachea directly
to
and the
anterior surface of the cervical s pin e . The level is checked radiographically and self-retaining retrac
tors are inserted beneath the longus coll i muscles. The disc is then excised. There are several variations of this operation.
Fig. 8.6
An autogenous iliac crest
Cloward anterior cervical
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fusion.
bone
dowel used in a
Surgical management of neck pain of mechanical origin 135
A
c
D Fig. 8.7
B
C5 vertebral body metastasis; (B) magnetic resonance imaging of th e same case; (C) a corpecromy has been performed and the body replaced with autogenous iliac crest. Internal fixation has been achieved with an anterior Orion plate; (D) an operative photograph of a similar case. (A) Plain radiograph showing a
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J 36 Clinical Anatomy ana Management of Cervical Spine Pain two adjacent levels. Rather than making two separate holes at the disc levels, the intervening vertebral body is drilled away, exposing the posterior longitudi Dal ligament which is usually also removed to expose the dura. The decompression is completed by remov ing the anterior part of the inferior margin of the upper vertebral body and the superior margin of the lower vertebral body. This allows for a very thorough decompression of the
cord in
cases of cervical
myelopathy and is also useful in isolated metastases in a single vertebral body. The most common graft material is autogenous iliac crest but substitutes may be used. Vertebral body replacements can be made from titanium and other
A
materials. Corpectomy can be used over longer lengths but it then becomes impossible to maintain the normal cervical lordosis and there is considerable stress on the two ends of a long strut graft (usually fibula).
Internal fixation
A wide variety of anterior plating devices is now available to supplement anterior fusion. The most commonly used are made of titanium, which allows postoperative MRl. The screws are usually of
a
ty pe
that locks into the plate, allowing adequate rigidity without having to penetrate the posterior cortex of the vertebral body. These plates are extremely useful i.n surgery for trauma and also provide immediate stability in multilevel fusions. The fusion rate for
B
single-level anterior cervical fusion is
Fig. 8.8 Two methods used to treat rheumatoid atlantoaxial instability. (A) Halifax c l am ps and bone graft; (B) titanium transfacet C 1 - 2 screws
very good
without fIXation (Robinson et al., 1962), and in non traumatic cases the use of a plate at one level may not add significant benefit.
Posterior cervical spine surgery
preSSion extends over several levels in
a
patient who
still has a lordotic cervical spine. This is much simpler
C/-2
than an anterior approach over multiple segments
Various methods of fusion at the Cl- 2 level have been devised.
Gallie and Brook's
fusions involve
wiring the posterior arch of the atlas to the axis with
interposing bone graft. Halifax interlaminar clamps are also used to achieve the same result. Magerl's technique of direct screw fIXation provides excellent results, including stability in rotation which is some what lacking with the other techniques. This can be combined with wiring techniques and braided cables are now often used in place of wires (Fig.
8.8).
and, with due care being taken to preserve the zygapophysial joi.nts, fusion is not necessary. The operation is done through a midline incision posteriorly over the spinous processes. The para spinal muscles are
stripped from the
bone and
retracted laterall y . The spinous processes are then removed and the laminae d rilled away or removed with bone nibblers and punch rongeurs. Great care must be taken when removing the inner cortex as the cord is compromised within a narrow canal and anything else inserted into the canal will further reduce the space available for the spinal cord. It is usually not necessary to remove the laminae of C2
Subaxial cervical spine
and the strong
muscular
attachments to the C2
spinous process can be left intact.
Myelopathy
When sufficient bone has been removed the dura Cervical
laminectomy
is frequently
used for
the
treatment of myelopathy, particularly when the com-
will bulge out of the defect and, unless there is
a
kyphosis, this will aHow the cord to move posteriorly.
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Surg ical management of neck pain of mechanical orig in 13 7 A fo ra minotomy c a n be performed t h rough a
Rad i c u l o p a thy
small incision placed in the mid l ine or m o re laterally
Sing le - o r mu l t i p l e-leve l ne rve root compressi on c a n
a t the affected leve l . By u s ing the same retractors as
be treated from a p o s t e r i o r a p p roach . This is most
for
suiteci to l a t e ra l ly p l aced soft disc p rotrusions o r fora mi n a l
na rrow ing,
pa r t icu l a rly
a
microdiscectomy,
lumbar
the
exposure
is
a d e qu a t e with a 2-cm skin incision . The operating
if i t i s due to
m icroscope provides su perior visu a lization and i.I l u
posterior osteop hytes (Fi g . 8 . 9 ) .
min a t i o n . The med i a l part of the zygapophysial joint is d rilled away to reveal the nerve roo t . This is then followed laterally u s ing a drill a n d a smaLl punch rongeur to undercut the bone l a te raUy, lea ving the j o in t in tact.
Pos terior ftxation The most common in d i cation for posterior ftx ation of the subaxial
cervical
i s tra u m a , pa rticula rly
spine
when posterior elements are invo l ved , as in zygapo physial j O in t facet dislocations. Posterior fixa tion c a n al so be used to imp rove sta bility aft e r extensive
or wide
lami nectomy
or
m u l t ip l e-level fo ramin o tomies (Fig . 8. 9). It is possi ble to perform a much wider decom pressio n o f a nerve root if t h e zygap o p hysiaJ j o i n t can be com p romised
but
,
if this
is
done
bilaterally
or
at
mul tiple levels, t h e consequent in s t a b i l i ty m a y be
A
p ro b l e m a ti c . There a re various wiring techniques w hich are quite
suitable
for
tra u m a .
Wires
can
be
passed
tlu'o ugh holes d r i.lled in sp inous processes, a ro und spinous processe s , under l a min a e , o r combinations of these. Ca bles can be substituted fo r wire and Halifax c lamps c a n also be used . After
laminectomy,
w iring
becomes
impractical
and posteri o r fixa tion is best achieved with lateral mass p lates. These plates a re fixed to the spine with screws passed into the lateral masses and provide excell e n t stability. The lateral mass at C7 i s quite thin a n d a screw may be p l aced in the ped icle at this level instead . At C2, a longer screw is used to pene trate the ped icle.
References Fielding, j.W , Cochra n , G . V B . , Lawsing, j. F II I et al. ( 1 974)Tears of the t ra ns v er se l iga ment of the atlas: a cli n i c a l and biomechanical study. ] Bone Joint Surg. A m. 56A 1 683 - 1 6 9 1 . Johnson, E. W. , Melvin, J. L. ( 1 97 1 ) Value o f electromyography in l u mbar radiculopathy. A rch. Phys. Med. Rehabil. 52: ..
2 3 9 - 24 3
Jipso n ,
B
V
Fig. 8.9 (A) Computed tomogra p h ic scan showing severe bilateral fora m inal stenosis at CS - 6 . The appeara nces at C4 - 5 were s i m ilar. (B) Latera l mass pl a t e s were used for sta bil ity after bilate ra l fora m i n otomies at C4 - 5 and C 5 - 6 .
S .). ( 1 984) RJ1 eumatoid a rthritis of the c e rv i c aJ s p i ne . Clin. Orthop. 182: 1 4 3 - 1 49. Me n ezes, A . H . , VanGilder, ).c. ( 1 988) Transo ral-trans p h a ryngeal
junction:
approach
ten-year
Neurosurg.
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to
the
ex p e ri en c e
69: 895 - 903 .
ante rior with
craniocervical
72
p a t i ems
.
.f.
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Chiropractic management of neck pain of mechanical origin M. I. Gatterman
Introduction Once a diagnosis has been made using conventional ap proaches such as taking a careful history, perform ing a thorough physical examination Cincluding orthopaedic and neurological tests, followed by im aging and laboratory tests as in d icat ed (Chapter 7), a diagnosis of mechanical spinal pain can be made. The mechanical lesion treated by chiropractors is referred to as a s pinal functional lesion - a subluxa tion. This has been defined as a motion segment in which alignment, movement integrity and/or physio logical function are altered (Gatterman and Hansen, 1994). Motion segments are the functional units of the body characterized b y articulat ing surfaces and their connecting structures. The s pinal motion se g ment of Junghanns is made up of two adjacent vertebra and the connecting tissues binding them to each other (Schmorl and J ung ha nns , 1971). The typical motion segment (or functional spinal unit) of the spine is a complex of three joints, the two zyga pophysial (posterior) joi nts and the interverteb ral disc. Movement at any one of these joints has a significant effect on the other two joints in the three-joint complex with degenerative changes affecting the quality and quantity of movement of the motion segment as a w hol e (Gatterman, 1990). In the cervical spine the two m os t cephalad ver tebrae form atyp ical motion segm e nts with no discs separating the anterior portions of these segments. The occipitoatlantal articulation has two paired condyles on the occiput that fit into the concave articular surfaces of the atlas. The body of the atlas in the atlantoaxial (Cl- 2) segment is replac e d by the peg-like odontoid process of the axis which is bounded anteriorly by the arch of the atlas and_,
post e r iorly by the transverse cruciate ligament. These two atypical motion segments allow for a considerable range of movement in the u p per cer vical region. The p ri ma r y motion at occiput-C1 is flexion and extension, while C 1- 2 allows for 50% of the total cervical rotation. Motion in the mid and lower cervical mot.ion and extension, and c oup le d lateral flexion and rotation. Consistent with spinal motion in general, movement in the cervical spine is guided by the morphology and plane of the zygapophysial articular surfaces. The exact mechanisms that cause subluxation of the zygapophysial articulations have not been estab lished. Biomechanical models that have been pro posed are listed in Table 9.1 (Mootz, 1995). Cervical subluxation synd rome s affecting the ce l-vical motion segments are commonly accompaniecl by neck pain and restriction of range of motion and may be localized to a spinal level by p alpation for painful zygapophysial joints and muscle spasm, and possibly b y functional f'J.diogrdphy (Dvorak et al., 1988).
Table 9.1
Il10dels of chiropractic sublu..Yation
Biomechanical models
Vertebral malposition Fixation caused by adhesion Fixation caused by synovial fold entrapment Fixation caused by nuclear fragmentation Disc deformation caused by tissue creep HypermobiIity and ligamentous laxity Mechanical joint locking Modified from Mootz
Copyrighted Material
(1995).
140 Clinical Anatomy and Management of Cervical Spine Pain
Aetiology of mechanical disorders The aetiology of cervical sp ine subluxation is thoug ht
to include progressive deg e nera tion , trauma and aberrant neurological reflex patter ns (Mootz, 1995). In addition to d e generative changes that occur with the ageing process, it has been speculated that frank trauma such as injury from a whiplas h mechanism, or microtrauma produced by faul ty sleeping posture and other h a bitual positions that produce repetitive strain can cause subllL'(ations. D ifferentiation of subluxa tions must include the recognition of subluxation due to overt pathology and the non-ma ni pula ble subluxa tion. A non-manipulable subluxation is a vert eb ral motion segment wit h radiological or cli nical features indicating that an adj us tive force or osseous manip ulation to this motion segment would be harmful or dangerous and is therefore contraindicated (peterson,
1995). T h.i s
extreme
form of subluxat ion has been
referred to as a medical subluxation or surgical subluxation (Sandoz, 1971) and it is imperative that the d.istinction be made on the basis of the magnitude of damage
to
sup p or tin g
structures
and
clinical
fi nd i ngs . Chiropractic treatment for mechanical pain of the cervical
spine is primarily
manipulation but
this
should only be used when it is considered safe in a particular case. Manipul a tion is a manual procedure that involves a carefully directed thrust to move a jOint past the physiological range of motion without the
exceeding
anatomical
limit
(Sandoz,
1976,
198\). In contrast to the non-manipulable subluxation, the subluxation chiropractors treat with ma nipulation is not commonly diagnosed by radiographic findings but rather is d e termin ed by palpatory indications (Haas and Pan z er, 1995) of l oca l i zed pain and muscle spasm (Bryner, 1989). A manipulable subluxation is one in w hi c h restricted function can be improved by manual thrust procedures (Gatterman and Hansen,
1994)
disc degenerates, this intrinsic balance mechanism is disrupted . With
reduced turgi d i ty,
the nucleus
as
pulp osus loses its hydrophilic properties , s egm enta l instability occurs
because
the
inelastic
ligaments
cannot shorten to compensate for the loss of disc height. The
resultant
increase
in
muscle
activity
required to stabUize the dege nera t i ng spine leads to the familiar pain - spas m - p a i n cycle. Hall
(1965) reviewed the pa ttern of degeneration
of the cervical spine. In the early stages, he noted cavities at the later;d margin of the anular fibres of the intervertebral disc that s prea d from one side to the
other with accompanying loss of disc height and ligamentous
laxity.
In
the
final
stage,
the inter
vertebral dist ance is greatly reduced and the bone structure becomes distorted by os te op hyte formation that results in stabilization of the e xcess mobility allowed by intersegmental l ig ame nts . In the following decade Kirkaldy-Willis et al. (1978) documented similar changes in the lumbar sp in e that provide
working model for the
a
diagnosis
and
management of mechanical low back pain (Kirkaldy Willis, 1984; Kirkaldy-WiJl.is and Hill, 1979). In this model, following the ini ti a l stage of dysfunction, loss of the intrinsic e q uili br i um creates an unstable phase of kinesiopathology duri ng which subluxation occurs (Keim and Kirkaldy-Willis, 1980). In the final stage, stabilization occurs, when motion in the z y gapophysial joints and disc becomes restricted by osteophytic proliferation; this stage is characterized by cartilage degeneration, loss of disc substance, soft-tissue fibro sis and the
formation of osteop h yt es
(Kci.m and
Kirkaldy-Willis, 1980). In the cervical spine the j oints of Luschka also exhibit degenerative changes, with the joint between the bodies of the vertebrae altered from a fibro cartil a ginous
amphiarthrosis
diarthrosis (Hall, intermediate
to
a ball-and-socket-shaped
1965). Sandoz (1989) described an
phase
prior
to
stabilization
during
which reversible j o int fixations (manipulable subluxa tions) occur. He noted that the restricted motion typically occurs at the extremes of se g men tal range of motion and may produce acute pa in of mechanical origin . In contrast, he noted that chronic segmental fD(ations enco untere d in the final stage of stabilization most co mmo nly occur at, or near, the
The process and mechanics of spinal degeneration
joint
neutral
pOSition
and
are
not
reversible
(Sandoz,
1989). The intrinsic forces that make the healthy spine a comparatively stable and mobile mechanical unit are vested in the elastic p roperties of some structures of the
spine.
Forces
acting
on the
typ ical
cervical
motion segment include the axial press ure of the head on the nuclei pulposi and the tension exerted
The mechanics of cervical spine injury
by ligamen ts holding each segment together, thus forming muscular
an
intri n s i c
force
is
equilibrium.
required
f ro m
Relatively the
little
contra ctile
elements to maintain erect p os tu re when this intrin sic e quili bri LUTI is preserved. \Vh en the intervertebral
Injuries
to
the
cervical
spine
accord ing to the structures . mechanism
Babcock,
Copyrighted Material
may
involved
be
classified
and by the
of inj u r y (Whitley and Forsyth,
1976).
Stability
is
dependent
on
1960; liga-
•
Chiropractic management of neck pain of mechanical origin J 41
mentous integrity and the absence o f neu rological
damage, loss of swbility and n eu rological da mage
insult. I nsta bi lity has been defined as:
With severe injuries, the anterior longitudinal liga ·
.
ment and intervertebral disc may be disrupted, with Loss of the ability of th e sp ine under ph ysio
logic load s to maintain relationships betw e e n
bilate ral zygapop hysia l join t dislocati o n O bv iousl y such cases require referral for approp riate surgical
vertebrae in such a way tha t there is neither
intervention (Chapter 8).
.
dam age n o r subsequent irritation to t b e spinal
Hyperextension injuries to tbe cervi ca l spine are blow to the foreh ea d or
cord or nerve roots and, in addition, there is no
most likely to occur f rom
development of inc a pa cit ating deformities or
from whi plash i nj ury produced by sudd en accelera
pain due to stmctural changes
(Whi te and
a
tion and are more common than h yp erflexi on in
Panjabi, 1978).
juries Hyperextension injuries frequently involve the .
atlantoaxial
j o in t ; hyperextension c ombined with
If severe i nst ability is suspec t ed based on severe pai n,
com p ressive forces such as occur with di ving acci
signs of neurological compromise or radiographic
de nt s may result in fractures and dislocations le ading
findings (McGregor a nd Mior,
1990), the pat ient
should be refe r red for a surgical opini on.
,
,
to insta bility and cord damage. Violent hyperexten sion with the fracture of the p edicl e s of C2 and forwards movement of C2
on
C3, prod u ces the
hang man s fracture. Burst fractures fro m comp ressive '
forces are rare and may in vol ve explosion of com
Cervical spine injuries
pressed disc material as well as disrupt ion of the
vertebral body.
In g e ne ra l, s pina l injuries are classified acc ording to the mechanism of injury (Table 9.2). Hyperflexion injuries most com m o nly result from blows to the back
of the
example (MVA).
head
-
,
1995). All these conditions require referral for appro· priate surgical in tervention ( C ha pter 8).
by
motor
ve b icle
accidents
of the vertebral body with ligamentous
Whiplash injuries is not a diagnostic term,
Whiplash
Table 9.2 oj injury
fl"'J.gments can prod uce
and forceful decelerations, for
prod uced
Pure flexion trauma may result in wedge
fracture
Displaced
cord injury in otherwise s tab le segments (F itz Ri tson
Classijlcation of spinal injuries by mechan.ism
but rather a
d escr iptive label that implies a mechanism of injury whereby the body comes to a sudden stop followed by a sudden snap of the unsuppor ted neck and head. By far the most c ommon cause of whiplash injury is the
HFperflexion injuries
MVA. The high incidenc e litigi ous nature of personal
syndrome Bilateral zygapophysial joint facet s ubl uxati o n Wedge compression fracture
injury and the freq uency of ongoing compl a ints
Flexion teardrop fl"aclllre
controversial subject which is dealt with in detail in
Anterior subluxation
Lateral flexion and rolation Injuries Rotational s ub l uxa t i on syndrome Unilater,ll zygapophysial joint facet subluxation
,
lo w speed
following
-
impact
ma ke
this
a
highly
Ch ap ter 5. The vu lne rabiH ty of the neck is created by the
3.5-5.5 kg head Qackson, 1977) sitting on top of the cervical spine with its multitude of joints 50 pair s of ,
muscles and a comp l ex ligamentous/capsular net
Hl'pereXlension. injuries Posterior subluxation syndrome
work. From this pe rsp ecti ve we have a ball (the head),
Hyperextension fracture-dislocarion
a flexible chain (the neck) and a rigid base (the upper
Fracture of the posterior arch spondylolisthesis
Traumatic
Laminar fracture
of tbe a tl as
back). It is not surpr ising that this structure is subj ect . to subluxation synd romes acco mpa nied by soft-tissue damage (Hohl, 1983) when a sudden motion whips
Vertical col71jJression injuries Compression fracl'ure Burst fracture Jefferson burst fracture (Cl) j1;Iixed mechanism injuries Atlanto·occipitaJ dislocation Odontoid fracture
the head and neck (most commonly in flexi on and extens i on)
.
Athletic injuries to the cervical spine
Total ligamentous disruption
Inj uries to the cervical sp ine include those from Modified from Fitz·Ritson
(19\)'»).
athletic activities such as football,
Copyrighted Material
soccer
,
skiing,
142 Clinical Anatomy and Management of Cervical Spine Pain diving, boxing , hockey and gymnastics. The mech anical
vulnerability
increases
the
risk
of of
the
hea d - neck
severe
disr uption
coupling of
the
mot ion segments. Bony elements , lig a men ts , discs and
muscular
supporting
structures
as
Table 9.3 Static and motion palpation procedures used in the manual tbe rojJy
well
as
neurovascular structures can be affected.
STATIC PALPATION
J\