Anatomy-Lec: LE 2 | TRANS 2 PDF

Summary

This document is a lecture note on the anatomy of the deep back, focusing on the vertebral column, its regions, muscles, and neurovasculature. The lecture was given by Zorba BNN R. Bautista & Steve HK T. Ng on September 16, 2024 and covers the spinal cord, meninges, nerves, and vessels.

Full Transcript

ANATOMY-LEC: LE 2 | TRANS 2

Deep Back
ZORBA BNN R. BAUTISTA, MD, DPBS & STEVE HK T. NG, MD | Lecture Date (SEPT/16/2024)

OUTLINE → Spinal cord and meninges
I. Vertebra IV. Joints → Nerves and vessels
A. Back A.Joints of Vertebral B. VERTEBRAL COLUMN / SPINE
B. Vertebral Column Bodies
or Spine
C. Vertebral Structure
B.Joints of Vertebral
Arches
The main part of the axial skeleton
It extends from the cranium to the apex of the coccyx 📖
II. Regional
Characteristics of the
C.Craniovertebral
Joints
the IV discs 📖
72-75 cms long (in adults); approximately ¼ is formed by

Has 5 distinct regions and a total of 33 vertebrae:
Vertebrae V. Muscles of the Back
→ Cervical (7)
A. Cervical Vertebra A.Extrinsic Back
→ Thoracic (12)
B. Thoracic Vertebra Muscles
→ Lumbar (5)
C. Lumbar Vertebra B.Intrinsic Back
→ Sacrum (5 segments) - fused together
D. Sacrum Muscles
→ Coccyx (4 segments) - fused together
E. Coccyx C.Suboccipital Region
F. Intervertebral VI. Neurovasculature
Discs A.Blood Supply
III. Ligaments B.Venous Drainage
A. Intersegmental C.Nerve Supply
Ligaments VII. Review Questions
B. Intrasegmental VIII. References
Ligaments IX. Appendix
SUMMARY OF ABBREVIATIONS
IV Intervertebral
ALL Anterior Longitudinal Ligaments
PLL Posterior longitudinal Ligaments

❗️
Must know
📣
Lecturer
📖
Book
📋
Previous Trans

LEARNING OBJECTIVES
✔ Describe the general structure of the vertebral column
✔ Distinguish the representative vertebra from the
cervical, thoracic, lumbar, and sacral regions
✔ Identify the deep back musculature, including the
muscles in the suboccipital region as to their general Figure 1. Vertebral column and its five regions. [Moore]
attachments, innervations, actions, blood supply and
lymphatic drainage
CURVATURES OF VERTEBRAL COLUMN
I. VERTEBRA
A. BACK
Composed of the following (from superficial to deep):
→ Skin and subcutaneous tissue
→ Muscles
▪ Superficial layer

group 📣
− Muscles of the posterior axioappendicular muscle

− Movement and positioning of the upper limbs 📖
▪ Deeper layers
− “True back muscles”

📖
− Movement and maintaining position of the axial
skeleton (posture)
→ Vertebral column
▪ Vertebrae
− Each vertebra is connected to an adjacent
vertebra via zygapophysial (facet) joints 📣 Figure 2. Curvatures of the vertebral column. [Moore]
▪ Intervertebral (IV) discs
− More flexible aspects of the vertebral column 📣 These curvatures provide additional flexibility
▪ Ligaments (for stability)
→ Ribs in thoracic region the IV discs 📖
(shock-absorbing resilience) aside from that provided by

LE 2 TRANS 2 TG-C10: G. Romero, *C. Rosales, M. Rosell, A. Roxas, C. TE: G. Romero, L. Sabico, L. AVPAA: A. Villanueva Page 1 of 21
Ruben, L. Sabico, L. Sagun, J. Salayo, R. Salazar Sagun
 PRIMARY CURVATURE (KYPHOSIS) − Have (articular surface) facets at its tips which

Anterior concavity
Kyphosis = concave/bending inwards/hunchbacking 📣 above or below 📣
forms joints with the skull above or the vertebrae

− With these joints, the processes determine the
In the thoracic and sacral regions

📣
Evident throughout life; due to differences in height of types of movements between the adjacent
vertebrae vertebrae of each region
Develops during fetal period
→ Only the primary curvature exists during the fetal life
Thoracic and Sacral Kyphosis
SECONDARY CURVATURE (LORDOSIS)

Posterior concavity
Lordosis = “convex”📣
In the cervical and lumbar regions

📣
Obvious in the beginning of infancy; due to differences in
height of IV discs
Cervical lordosis
→ starts when an infant gains control of their necks📣 (to

📖
raise the head while pronated and to hold the head Figure 3. Functional components of the vertebra. [Moore]
erect while sitting ) Vertebral foramen
Lumbar lordosis → Formed by the posterior surface of vertebral body and

sacrum 📖
→ Ends at lumbosacral angle at the junction of L5 with the vertebral arch
→ Spinal cord & nerves pass through here

begins to stand and walk 📣
→ Evident within the first year; starts when an infant Vertebral canal
→ Formed by the succession of vertebral foramina in the
FUNCTIONS OF VERTEBRAL COLUMN articulated vertebral column
Protects spinal cord and spinal nerves → Contains the spinal cord, roots of spinal nerves,
Supports the weight of the body superior to the level of meninges, vessels
the pelvis Vertebral notches
Provides a partly rigid yet flexible axis for the body where → Superior vertebral notch and inferior vertebral notch
the appendicular skeleton will be attached → Two notches form the IV foramen (lateral view)
Plays an important role in posture and locomotion → Anteriorly: corresponding projection of the vertebral
body

stable, flexible, and movable 📣
To perform all these functions, the vertebral column must be → Posteriorly: between the superior and inferior articular
processes
C. VERTEBRAL STRUCTURE
PARTS OF A TYPICAL VERTEBRAE
Vertebral body
→ large, thick, and ovoid structure 📣
→ carries most of the weight of each segment 📣
Vertebral arch
→ 2 components: pedicles and lamina
▪ Pedicles (“feet”)
− Short, cylindrical processes
− Project posteriorly from the vertebral body
▪ Laminae (“roof”)
− 2 broad, flat plates of bone that unite in the
midline
− Where the protrusions or processes emerge
− Mainly for muscle attachment
7 Processes
→ 3 for muscle attachments
▪ Serve as levers, facilitating the muscles that fix or Figure 4. Lateral view of vertebrae showing IV
change the position of the vertebrae foramen. [Moore]
▪ Spinous process (1) Intervertebral foramina

junction of the laminae 📣
− Projects posteriorly from the vertebral arch at the → Formed by the superior and inferior vertebral notches of
adjacent vertebrae and the IV discs connecting them

❗️
▪ Transverse processes (2) → Where the spinal nerves emerge from the vertebral
− Projects posterolaterally from the junctions of the column
pedicles and laminae → Location of the spinal (posterior root) ganglia
→ 4 for formation of articular joints Intervertebral discs
▪ Superior articulating processes (2) → Attached to the vertebral bodies through the inferior
▪ Inferior articulating processes (2) vertebral “end plate” and the superior vertebral “end

📣
▪ AKA zygapophyses plate” of the posterior and inferior vertebral bodies,
− Also arise from the junctions of the pedicles and respectively
laminae → End plates are composed of hyaline cartilage

ANATOMY Deep Back Page 2 of 21
 → Composed of: Greatest range and variety of movement (among all the
▪ Annulus fibrosus: fibrous outer covering vertebral regions)
▪ Nucleus pulposus: pulpy gel-like core → Flexion
→ Extension
→ Lateral flexion
→ Limited rotation
→ Circumduction
7 cervical vertebrae

Figure 5. Medial view of internal aspects of vertebral bodies
and vertebral canal [Moore]
NICE TO KNOW: NEUROANATOMY 📣
At the spinal cord level, there is a dorsal horn (purely
sensory) and ventral horn (purely motor)
As the roots come out, they would eventually merge to
form the spinal root
As it emerges from the IV foramen, it would divide into
the dorsal and ventral rami

Figure 7. Cervical vertebra [Moore]
TYPICAL CERVICAL VERTEBRAE
Note: In Moore, C3-C7 are classified as typical vertebrae but Doc
Bautista mentioned in the recorded lecture that C7 has
characteristics which sets it apart from the typical ones.
C3-C6 VERTEBRA
Vertebral End plates
→ brim around the body where IV discs will be
seated/attached
→ flat, slightly concave surfaces on the superior and

📖
inferior aspects of the vertebral bodies
Have uncinate processes (Uncus)

Figure 6. Spinal cord cross-section through lumbar
(unique to the cervical vertebra) 📣
→ It is a brim around the bodies that tend to arch upwards.

Transverse foramina (foramen transversarium)
vertebra. [Netter] → Hole on either side of the transverse processes
II. REGIONAL CHARACTERISTICS OF THE → Present in C1-C7 vertebra
VERTEBRAE Spinous process: short and bifid tip
→ Due to the tension created by the muscle attachments

📣
A. CERVICAL VERTEBRA to the posterior neck (e.g. trapezius)
Skeleton of the neck → Less common in black individuals
Seem to be very flimsy, especially C1 Superior articular facets are directed supero-posteriorly
Vertebral body: small but wide and inferior articular facets are directed infero-anteriorly

📣
Vertebral foramen: large and triangular to ensure that the cervical vertebrae has the most amount
→ It is large since the thick brainstem courses through the of movements
vertebral foramen, coming out of the foramen magnum, Vertebral foramen: larger than usual, triangular
and connecting the spinal cord and the brain.
📖
→ To accommodate cervical enlargement of spinal cord

facing forward from the superior aspect 📣
The articulating facets have a nearly horizontal orientation,

→ Facets in nearly horizontal orientation + small body +
small amount of surrounding body mass (only neck
muscles and neurovascular structures coming up and
down) = greatest range of motion
IV discs are at their thickest

ANATOMY Deep Back Page 3 of 21
 Figure 8. Typical cervical vertebrae [Lecturer’s PPT]
ATYPICAL CERVICAL VERTEBRAE
C1 VERTEBRA (ATLAS)
NO body and spinous process
Anterior and posterior tubercle
→ Anterior: shorter arches
→ Posterior: longer arches and noticeable grooves where
vertebral artery passes through Figure 9. C1 vertebrae [Netter]
Ring-shaped with paired lateral masses and has the C2 VERTEBRA (AXIS)
transverse processes on the either side The axis of the atlas
Facets in superior view:
📖
Has a large bifid spinous process that can be felt deep in
→ Form the joint with the occipital condyles of the skull the nuchal groove
→ Posterior to each of these superior facets, there are
Strongest of all cervical vertebrae because of the most
grooves for the vertebral artery
obvious structure which is the dens (odontoid process)
Facets in inferior view:
→ Inserts into the ring of the atlas in the formation of the
→ Each of these facets are involved in the attachment to
atlantoaxial joint (ONLY synovial pivot joint in the
the C2 vertebrae
vertebral column)
Weakest of all cervical vertebrae
→ This joint is also found in between the articulating facets
→ The bone that fractures during hanging compresses the
brainstem, which eventually causes the demise
Widest of the cervical vertebrae (from tip to tip of its
📣 on either side
→ Dens: Superiorly protruding part of the vertebral body,
transverse processes)
Superior articular surface articulates with the occipital
facet.📣
articulates with the axis at the posterior articular

▪ It protrudes upwards, allowing the atlas to articulate
condyles articulating to the base of the cranium.
→ It is a condylar joint (atlanto-occipital joint); aids in
around which the atlas rotates. 📣
with its posterior surface; the dens acts as the axis

the head (“YES” joint) 📣
nodding movement particularly flexion and extension of
▪ Leaves a wide area for the brainstem
Inferior Articular Surface articulate with C2 or axis which
forms a part of the atlantoaxial joint.
📣
▪ “NO” joint enabling head rotation to the left and
right.
▪ To maintain its position, several ligaments secure the
dens:
− The apical ligament of the dens and alar

📣
ligament are the deepest ligaments, keeping the
dens close to the base of the skull.

head overturning. 📣
− The alar ligament specifically prevents excessive

− The cruciform ligament further secures the
atlantoaxial joint, consisting of the superior

and transverse ligament of the atlas. 📣
longitudinal band, inferior longitudinal band,

− Cruciate ligament (located posteriorly when
viewed superiorly) and alar ligaments support the
atlantoaxial joint at the odontoid process

ANATOMY Deep Back Page 4 of 21
 → Sloping or angled inferiorly like the thoracic spinous
processes
Smaller or absent transverse foramen
→Transmit only small accessory veins
📖

Figure 10. C2 vertebrae [Netter]

Figure 11. C7 vertebrae [Netter]
Table 1. Summary of the major characteristics of Cervical vertebrae
Part Characteristics
Vertebral Small and wider from side to side than
body anteroposteriorly
Superior surface concave with uncus of
body (uncinate process)
Inferior surface convex
Vertebral Large and triangular
foramen
Transverse Foramina transversarii and anterior and
Processes posterior tubercles;
Vertebral arteries, accompanying venous
and sympathetic plexuses pass through
foramina transversarii of all cervical
vertebrae except C7
C7 transmits only small accessory
vertebral veins
Articular Superior facets directed
Processes superioposteriorly
Inferior facets directed inferio-anteriorly
Obliquely placed facets are most nearly
horizontal
Spinous Short (C3-C5) and bifid (C3-C6);
Process process of C6 long, that of C7 is longer
(thus called “vertebra prominens”)
Movement Greatest range and variety of
movement: flexion, extension, lateral
flexion, limited rotation, circumduction

[Lecturer’s PPT]
Figure 10.1. C1 to C4 Vertebrae
C7 VERTEBRA (VERTEBRA PROMINENS)
Transitions from cervical to thoracic
The spinous process is the longest of all cervical spinous
processes

name vertebra prominens 📣
→ The first bone that you feel on your nape, hence the

→ Almost as long as thoracic spinous process

ANATOMY Deep Back Page 5 of 21
 B. THORACIC VERTEBRA
→ Rotation ❗️
▪ Only allowed movement in thoracic vertebrae
▪ Allows rotation of thorax up to 45 degrees
→ Limited due to zygapophyseal joint and ribs:
▪ Flexion
▪ Extension
▪ Lateral flexion
ATYPICAL THORACIC VERTEBRAE
T1 - T4 VERTEBRA

T1 vertebra 📋
Have some features of cervical vertebrae

→ Spinous process: long, almost horizontal; may be as
prominent as the vertebra prominens
→ Superior edge: has a demifacet that contributes
Figure 12. T6 vertebra: lateral view[Netter] articular surface of the second rib
Located in the upper back and provides attachment for the T9 - T12 VERTEBRA
ribs associated with it.
Spinous process angulation is oriented inferiorly 📣📣 Have some features of lumbar vertebrae (transitional
Articulating facets are almost completely vertical
areas)
T12 vertebra 📋
Costal facets 📖❗️
→ Limits the movement of the thoracic vertebrae

→ Primary characteristics features of thoracic vertebrae
→ Shortest spinous process among the thoracic vertebrae
→ Massive body
→ Thick pedicles and laminae
→ For articulation with the ribs → Solitary costal facets
▪ 2 for the head → Superior articulating facet: vertical and pointing
▪ 1 for the tubercle posteriorly
→ Superior and Inferior costal facets articulate each single → Inferior articulating process oriented laterally (lumbar
head of the rib vertebrae characteristic)
structures 📋
Location may be approximated by the level of the

→ T2: at the level of the sternal notch, which is at the
superior or proximal end of the sternum
→ T9: at the level of the xiphoid process, which is at the
inferior or distal end of the sternum
TYPICAL THORACIC VERTEBRAE

Figure 13. T2 vertebrae[Netter]
Figure 13. T6 vertebrae superior[Netter] and lateral view[Lecture
PPT]] Table 2. Summary of the major characteristics of Thoracic vertebrae
Part Characteristics
T5 - T8 VERTEBRA Vertebral Heart-shaped and larger than cervical
The body has one or two costal facets for articulation with body vertebrae
head of rib Vertebral Circular and smaller than cervical and
Transverse processes no longer have the transverse Foramen lumbar vertebrae
foramina instead they’re much longer. They also have Transverse Long and strong; extends
another facet called costal facets. Processes posterolaterally
→ Articular facets: vertically oriented Length diminishes from T1-T12
Articular processes tend to face anteriorly and T1-T10 have facets for articulation with
posteriorly. tubercle of rib
→ Flexion and extension is limited in the thoracic section. Articular Nearly vertical articular facets
and extending in this area. 📣
→ Bones and muscles are actually in the way from flexing Processes Almost limits the movement of the
thoracic vertebrae

→ Rotating in the thoracic area aids along with the rotation
of the cervical area to look behind the neck and back.
Spinous processes: long, downward sloping,
📣 Superior facets: directed posteriorly
and slightly laterally
Inferior facets: directed anteriorly and
posteroinferiorly overlapping. Sometimes it reaches all the slightly medially
way down to the vertebral body of the next vertebrae. Planes of facets lie on an arc centered in
→ Helps in limiting the extension of the thoracic vertebrae the vertebral body
Attachment of ribs
Movement permitted:

ANATOMY Deep Back Page 6 of 21
 Spinous Long, slope posteroinferiorly
Processes (remarkably inferior)
Tips extend to vertebral body below
(overlapping)
Movement Only rotation (of the thorax)
Limited flexion, extension, and lateral
flexion due to:
→Presence of ribs and sternum
anteriorly
→Vertical orientation
→Overlapping spinous processes
C. LUMBAR VERTEBRA

Figure 15. Mammillary and Accessory processes[Netter]
L5 VERTEBRA
Figure 14. Lumbar vertebra [Netter] Massive body and transverse processes
Largest of all movable vertebrae
other regions 📋
Largest and heaviest vertebrae in terms of mass than the

Bigger as you go down the vertebral column to

Carries the weight of whole upper body
Body markedly deeper anteriorly
Markedly taller anteriorly compared to the posterior side
accommodate the weight of the rest of the body above it → Responsible for the lumbosacral angle between the
Denser and thicker than the rest of the vertebral column. lumbar and sacral region of vertebral column
Vertebral foramen: triangular Site of lumbar puncture
→ Bigger, it accommodates the lumbar section of the → During flexion, spaces widen allowing the procedure to
spinal cord that tends to be thicker because it has more be done (extraction of synovial fluid and injection of
sections and nerves which supply the muscles of the anesthesia)
lower extremities
→ It also houses the cauda equina. 📣
▪ Spinal cord ends around the L1 or L2 region in
adults, and then continues as cauda equina, giving

nerves that are extending downward.
Spinous process:
📣📋
off spinal nerves up to S5. It is only the spinal

→ Short and sturdy. Looks like hatches or axes.
→ Thick, broad
→ Hatchet-shaped
Articular processes tend to face inward and outwards
respectively.
Movements:
→ Facilitates: flexion, extension, lateral flexion
→ Prohibits: rotation Figure 16. L5 vertebrae[Netter]; Medial view of bisected column
▪ Most of the rotation occurs in the thoracic and cervical from left with ribs, cranium, and pelvis[Lecture PPT]
vertebrae. Table 3. Summary of the major characteristics of Lumbar vertebrae
Presence of additional processes for attachment of Part Characteristics
muscles to support upper body Vertebral Massive
→ Mammillary process body Kidney-shaped (when viewed
▪ Provide attachment to multifidus muscle and superiorly)
intertransversarii muscle Vertebral Triangular
▪ Located at the posterior surface of the superior Foramen Larger than in thoracic vertebrae but
articular process smaller than in cervical vertebrae
→ Accessory process Transverse Long and slender
▪ Provide attachment to intertransversarii muscles only Processes Accessory process on posterior surface
▪ Located at the posterior surface of the base of each of base of each process
transverse process Articular Extend vertically
Processes Superior facets: oriented
posteromedially
Inferior facets: oriented anterolaterally
Spinous Short and sturdy
Processes Thick, broad
Hatchet-shaped

ANATOMY Deep Back Page 7 of 21
 Movement Facilitates: Flexion, extension, lateral E. COCCYX
flexion (at the waist)
Prohibits: Rotation
4-5 segments of small triangular bone
Fused rudimentary coccygeal vertebrae 📖
D. SACRUM
eminence 📖
Skeletal remnant of the embryonic tail-like caudal

Very limited movement
→ When sitting, it may flex anteriorly, indicating that it is
receiving some weight
Attachment for pelvic muscles and levator ani muscles
Pelvic surface
→ concave and relatively smooth
Posterior surface
→ rudimentary articular processes
Transverse processes
→ short, connected to the sacrum
F. INTERVERTEBRAL DISCS

Figure 18. Intervertebral discs[Netter]
Provide strong attachment between vertebral bodies
Figure 17. Anterior and posterior view of the sacrum and 20-25% of length (height) of the vertebral column
coccyx[Netter] Absorb shock, supports movement, and allow for some
S1-S5 bones, including the transverse and spinous flexibility of the vertebral column
processes, are fused together to form one huge bony Composed of 2 layers
plate → Annulus Fibrosus
Sacral Promontory Ring of concentric lamellae

→ Important obstetrical landmark.
Anterior (Pelvic) Surface: smooth
📣
→ Anterior projecting edge of the body of the S1 vertebra Oblique direction of fibers in each lamellae that run
perpendicular to each other. This gives the tensile
and elastic properties for the rest of the vertebrae.
Sacral foramina

→ 4 pairs 📖
→ Houses the spinal nerves for the sacral region 📣 Outer dense fibrous connective tissue covering
Envelops nucleus pulposus
Weakened areas in annulus fibrosus cause nucleus

📖
→ For the exit of the posterior and anterior rami of the pulposus to herniate - Herniated discs
spinal nerves → Nucleus Pulposus
Posterior Surface: Rough, convex, and marked by five Central core; Pulpy center
prominent longitudinal ridges or crests serve as muscle Almost 88% water in adults but eventually dries up
attachment for lower back and lower extremities. and hardens with age.
→ Median sacral crest: Fused portion of the spinous Act as a semifluid fulcrum on vertebral movement
processes of the sacral vertebrae where weight is distributed.
→ Lateral sacral crest: Fused portion transverse Gel-like substance that allows shock absorption
processes III. LIGAMENTS
→ Intermediate sacral crest: Fused portion of the Structures that support the vertebral column
articular processes
Vertebral Body Ligament:
→ Sacral Hiatus: Inverted U-shaped, Lack of laminae in
→ Longitudinal as it goes from the very top to the bottom.
S4 and S5, leads into sacral canal
→ Anterior Longitudinal: prevents hyperextension
→ Sacral canal
→ Posterior Longitudinal: prevents hyperflexion
▪ It is the continuation of the vertebral canal.
Posterior Ligaments
▪ It contains the bundle of spinal nerve roots arising → Supraspinous
inferior to the L1 vertebra called cauda equina. → Interspinous
▪ Note: Spinal cord ends at L1-L2 → Ligamentum Flavum
→ Sacral cornua: Inferior articulating processes of S5
vertebrae

ANATOMY Deep Back Page 8 of 21
 A. INTERSEGMENTAL / LONGITUDINAL LIGAMENTS → Bridging fat and vessels between the ligament and
\
bony surfaces
ANTERIOR LONGITUDINAL LIGAMENTS
Table 4. ALL vs PLL
ALL PLL
Characteristic Largest Narrower
Widest Weaker

Function ❗️

Strongest
Prevents
hyperextension
Weakly resists
hyperflexion
(Only ligament that Helps prevent
limits extension) herniation of the
nucleus pulposus
Attachment Anterolateral Posterior to
aspect of vertebral vertebral bodies
bodies IV discs
Location C1- sacrum Within vertebral
canal
Figure 19. Anterior Longitudinal Ligaments[Netter] C2-sacrum
Additional Only ligament that (+) nociceptive
Largest, widest, and strongest ligament in the vertebral
Information encompasses the nerve endings
column
whole spinal (+) lateral
aspects of the vertebral bodies and IV discs
Extends from the cervical area to the sacrum
📖
Fibrous band that covers and connects the anterolateral

r
column transverse
projections
→ Anterior Atlantoocipital membrane B. INTRASEGMENTAL / ACCESSORY LIGAMENTS
Functions:
\

📖
LIGAMENTUM FLAVUM
→ Prevents hyperextension of the vertebral column
→ The only ligament that limits extension Broad, pale yellow bands of elastic tissue
First structure that tears when the back is Thickest in lumbar region because it gets the most work
Begins at C3
hyperextended
Functions:
→ Maintain stability of the joints between vertebral bodies → Resist separation of vertebral lamina by limiting abrupt
POSTERIOR LONGITUDINAL LIGAMENTS flexion of vertebral column
→ Help preserve normal curvatures of vertebral column
→ Assist with straightening of column after flexing

Figure 21. Ligamentum Flavum[Netter]

INTERSPINOUS LIGAMENT
Thin
Connects adjacent spinous processes, attaching from root
to apex of each process

spinous process ❗️
Location: in between superior and inferior borders of

Function: Inhibits flexion
Figure 20. Posterior Longitudinal Ligaments[Netter]
SUPRASPINOUS LIGAMENT
Much narrower, somewhat weaker than ALL
Runs within the vertebral canal along the posterior aspect Most superficial; Cord-like
of the vertebral bodies Connects tips of spinous processes from C7 to sacrum
Mainly attached to the IV discs Merges superiorly with the nuchal ligament at the back of
Weakly attached to posterior aspect of C2 to sacrum the neck
Well-provided with nociceptive (pain) nerve endings Function: Inhibits hyperflexion and excessive lateral
Functions: flexion
→ Weakly resists hyperflexion of the vertebral column
❗️
INTERTRANSVERSE LIGAMENT
→ Prevents or redirects posterior herniation of the nucleus Connects adjacent transverse processes
pulposus Characteristics per region:
→ Cervical: scattered fibers

ANATOMY Deep Back Page 9 of 21
 → Thoracic: fibrous cords vertebral foramen or between the internal surface of the
→ Lumbar: thins and membranous lamina is the Ligamentum Flavum. To pass through the
Function: Limits contralateral lateral flexion structures, order is also important.
→ These structures need to be pierced in order to
have access to the vertebral canal for multiple reasons
such as spinal anesthesia and diagnostic samples from
the spinal fluid.
IV. JOINTS
The joints of the vertebral column include:
→ Joints of vertebral bodies
📖
→ Joints of vertebral arches
→ Craniovertebral joints (atlanto-axial and
atlanto-occipital)
→ Costovertebral joints
→ Sacro-iliac joints
A. JOINTS OF VERTEBRAL BODIES

weight-bearing and strength
→ Fibrocartilaginous fusion
❗️
Symphyses (secondary cartilaginous joints) designed for

▪Remember: IV discs are representative of
fibrocartilage
→ Intervertebral discs act as a shock absorber
Figure 22. Red: Interspinous ligament; Blue: supraspinous Articulating surfaces connected by intervertebral discs
ligament; Green: intertransverse ligament [Moore] B. JOINTS OF VERTEBRAL ARCHES
LIGAMENTUM NUCHAE/ NUCHAL LIGAMENT Zygapophysial joints (facet joints)
Strong, broad; fibroelastic tissue from the midline base of
the skull to the spinous processes of cervical vertebrae. movement they allow 📣
→ Orientation of facet joint dictates what type of

Plane synovial joints (gliding-type) between the
Extends as a median band from the external occipital
protuberance at the back of the skull and posterior border superior and inferior articular processes of adjacent
vertebrae surrounded by a thin joint capsule
cervical vertebrae
Functions:
❗️
of the foramen magnum to the spinous processes of the
Permits gliding movements between articular processes
NOTES
→Provides attachment for muscles that attach to the Shape and disposition of articular surfaces:
spinous processes of vertebrae at other levels determines the types of movement possible
→ Inhibits hyperflexion of the neck → Remember facet joint orientation of each spinal
▪ Flexion of the neck causes palpation of the ligamentum segment
nuchae from the external occipital protuberance down
to the C7 vertebral prominence
Size of IV disc: determines range of motion
→ Large IV disc in cervical and lumbar segments ❗️
C. CRANIOVERTEBRAL JOINTS
ATLANTO-OCCIPITAL JOINT

📖
Formed between the atlas (C1 vertebrae) and occipital
bone of the cranium

“YES” joint ❗️
Synovial joint of the condyloid type

→ Allows you to nod your head 📣
→ Allows flexion and extension of the neck, and also
permits lateral flexion, rotation as a condyloid joint
Anterior and posterior atlanto-occipital membranes
📋
📋
stabilize or prevent excessive movement of the
atlanto-occipital joints.
Anterior Atlanto occipital membrane
→ Extension of the anterior longitudinal ligament. It covers
anteriorly a portion of the atlantoaxial joint space
Posterior Atlanto occipital membrane
→ Extension of the Ligamentum Flavum.
→ This is where the vertebral body pierces.
→ Vertebral artery passes through the transverse foramina
all the way to C1, in order to have access to the cranium,
supplying blood to posterior side of brain
Figure 23. Ligamentum nuchae on right lateral view [Netter]
NOTE
Supraspinous ligament runs along the tips of the
spinous processes. In between the spinous processes, is
the interspinous ligament. Then, right before the

ANATOMY Deep Back Page 10 of 21
 Figure 24. Atlanto-occipital Joint [Lecture PPT]
Figure 27. Atlanto-axial articulations [Lecture PPT]
ATLANTO-AXIAL JOINT

vertebra)📖
Formed between the atlas (C1 vertebrae) and axis (C2

Synovial joint with NO IV disc
→ Atlas has no vertebral body
Alar ligament and Cruciate ligament supports this joint at
the odontoid process
Posterior longitudinal ligament extends to tectorial
membrane

❗️
→ Acts as covering of cruciate ligament 📣
“NO” Joint

📖
→ Pivot joint that allows you to shake your head “no”
→ Allows rotation
📣 Figure 28. Associated ligaments that stabilize joints [Netter]
V. MUSCLES OF THE BACK
Most body weight lies anterior to the vertebral column;
consequently many strong muscles attached to the

necessary to support and move the column
2 Major Groups of Back Muscles
📖
spinous and transverse process of the vertebrae are

→ Extrinsic Back Muscles
Superficial (Limb)

Intermediate (Respiration)

→ Intrinsic (Deep) Back Muscles (Vertebral Column)
Figure 25. Movement of Atlanto-axial joints [Moore] Superficial

Intermediate

Deep

A. EXTRINSIC BACK MUSCLES
Separated from the intrinsic muscles via the
thoracolumbar fascia

📖
Extrinsic back muscles produce and control limb and
respiratory movements

❗️
→ Superficial (posterior axio-appendicular): produce
and control movement of limbs

❗️
→ Intermediate (serratus posterior): for respiration and
proprioception
SUPERFICIAL EXTRINSIC LAYER

Figure 26. Atlanto-axial joint [Lecture PPT]
Three atlanto-axial articulations 📖
→ Permits the head to move from side to side
→ Lateral atlanto-axial joints (2)
▪ Left and right atlanto-axial joints
▪ Gliding-type synovial joints
▪ Between the inferior facets and lateral masses of C1
and the superior facets of C2
▪ Two facet joints at the articulating processes of
vertebral arch
→ Median atlanto-axial joint (1)
▪ Pivot joint
▪ Between the dens of C2 and anterior arch of the atlas
Figure 29. Superficial Extrinsic Back Muscles [Netter’s]
▪ At odontoid process and the anterior arch of atlas

ANATOMY Deep Back Page 11 of 21
 Includes the posterior axioappendicular muscles
(trapezius, latissimus dorsi, levator scapulae, and
rhomboids)
→These muscles connect the axial skeleton (vertebral
column) with the superior appendicular skeleton
(pectoral girdle and humerus)
→Innervated by the anterior rami of cervical nerves
which act on the upper limb
→ Produce and control limb movements
Table 5. Superficial Extrinsic Back Muscles.
Muscle Description
Trapezius Shape: Large and triangular
Innervation: Spinal accessory nerve
(CN XI)
Action:
→ Superior fibers: elevate scapula
→ Middle fibers: retract scapula
→ Inferior fibers: depress scapula
Latissimus Shape: Large and fan-shaped
dorsi Innervation: Thoracodorsal nerve
Action: Elevate and rotates scapula
Rhomboid Shape: Quadrate
major and → Rhomboid major is thin, flat, and wider
minor Innervation: Dorsal scapular nerve
Action: retracts scapula and rotates
glenoid fossa
INTERMEDIATE EXTRINSIC LAYER
For respiration and proprioception

📋📋
SERRATUS POSTERIOR Figure 30. Intermediate Extrinsic Back Muscles [Netter]
Wing-like, long, and thin muscles
Action: proprioception and respiration
Found in different part of the thoracic wall 📋 “True back muscles” 📣
B. INTRINSIC (DEEP) BACK MUSCLES

📣📋
Thoracolumbar fascia - found underneath the serratus
SERRATUS POSTERIOR SUPERIOR posterior muscles and it covers the entire back
Located deep in relation to the rhomboid muscles Everything deep to your thoracolumbar fascia
Innervated by the intercostal nerves
SERRATUS POSTERIOR INFERIOR
Located deep in relation to the latissimus dorsi
Table 6. OINA of Serratus Posterior
Serratus posterior Serratus posterior
superior inferior
Superior Nuchal ligament, Spinous processes
Attachment spinous process of of T11-L2 vertebrae
C7-T3 vertebrae
Inferior Superior borders of Inferior borders of
Attachment 2nd-4th ribs 8th-12th ribs near
their angles
Innervation 2nd-5th intercostal Anterior rami to Figure 31. Thoracolumbar Fascia [Netter]
nerves T9-T12 thoracic SUPERFICIAL INTRINSIC LAYER
spinal nerves
Main action Proprioception Proprioception
(elevates the ribs) (depresses the
ribs)

Figure 32. Muscles of the superficial intrinsic layer [Moore]

ANATOMY Deep Back Page 12 of 21
 SPLENIUS
Most superficial back muscle ❗️
Thick and flat muscle at the upper portion 📖
LONGISSIMUS
Forms the intermediate column
From the iliac crest all the way up to the mastoid process
Lies on the lateral and posterior aspect of the neck,

📋
covering the vertical muscles somewhat like a bandage
One muscle with two leaves (bipennate):
📖 or the base of the skull

📋
Only muscle that extends from the pelvis to the area of
mastoid process in the skull
→ Splenius cervicis: ends at C1-C3/C4 SPINALIS
cervical vertebrae 📣
▪ Inserts to the transverse processes of the upper
Forms the medial column
→ Splenius capitis: extends to the mastoid process of
skull
Several short muscles that transverse three to four
segments of the vertebral spine, upward and downward
In between the spinous process from lumbar to thoracic
📋
of the skull going to the mastoid processes
The splenius leaves are NOT EXCLUSIVE TO ONE SIDE.
📣
▪ Inserts in the more lateral aspect of inferior nuchal line
and within cervical region

📣❗️
It is one whole muscle that has a splenius cervicis and
splenius capitis parts on each side.
Table 7. OINA of Splenius Muscle
Proximal Nuchal ligament and spinous
Attachment processes of C7 to T3 or T4 vertebrae
Distal Splenius capitis: Fibers run
Attachment superolaterally to mastoid process of
temporal bone and lateral third of
superior nuchal line of occipital bone
Splenius cervicis: Tubercles of
transverse processes of C1-C3 or C4

Nerve Supply
Main action
vertebrae
Posterior rami of spinal nerves ❗️
Acting alone: laterally flex neck and Figure 34. Erector Spinae Muscles [Moore]
rotates head to side of active muscles Table 8. OINA of Erector Spinae Muscle
Acting together: extend neck and Proximal Arises by a broad tendon from
head Attachment posterior part of iliac crest, posterior
surface of sacrum, sacro-iliac
INTERMEDIATE INTRINSIC LAYER
ligaments, sacral and inferior lumbar
spinous processes, and supraspinous
ligament
Distal Iliocostalis: lumborum, thoracis,
Attachment cervicis; fibers run superiorly to angles
of lower ribs and cervical transverse
processes
Longissimus: thoracis, cervicis,
capitis; fibers run superiorly to ribs
between tubercles and angles to
transverse processes in thoracic and
cervical regions and to mastoid
process of temporal bone
Spinalis: thoracis, cervicis, capitis;
fibers run superiorly to spinous
processes in the upper thoracic region

Nerve Supply
Main action
and to cranium
Posterior rami of spinal nerves ❗️
Acting bilaterally: extend vertebral
Figure 33. Erector Spinae Muscles [Netter] column and head; as back is flexed,
ERECTOR SPINAE MUSCLES control movement via eccentric
At the back, there is a narrow furrow at the median or the contraction,
“small of the back” and on each side of it, there is a Acting unilaterally: laterally flex

📣
“muscular hump” which is ideally where the erector spinae vertebral column

muscles are
Chief extensors of the vertebral column ❗️ 📋 column ❗
Chief extensors of the vertebral

Often referred to as the “long muscles” of the back DEEP INTRINSIC LAYER: MAJOR LAYER
Dynamic (motion-producing) muscles
Combination of three muscles: iliocostalis, longissimus,
spinalis
Collective
muscles ❗️called transversospinalis group of

Forms the lateral column
ILIOCOSTALIS adjacent vertebrae 📣
→ Called “transversospinalis” because it transverses

→ From the transverse processes to the spinous
“Ilio” from iliac crest and “costalis” to the ribs processes

ANATOMY Deep Back Page 13 of 21
 Attachment Fibers pass obliquely superomedially
to entire length of spinous processes

❗️
located 2-4 segments superior to
proximal attachment
Nerve Supply
Main action Extension ❗️
Posterior rami of spinal nerves

Stabilizes the vertebrae during local
movements of vertebral column
ROTATORES
Smallest of the 3 muscles in the deep intrinsic major layer
From the transverse process below to the spinous process
above
Will allow for a little bit of rotation of the vertebral column
Table 11. OINA of Rotatores Muscle
Figure 35. Deep Intrinsic Muscle Layer [Lecturer’s PPT] Arises from transverse processes of
Proximal
vertebrae; best developed in thoracic
SEMISPINALIS Attachment
region

📋
Most superficial of the deep intrinsic major layer muscles Fibers pass superomedially to attach to
junction of lamina and transverse
cervical area and to the base of the skull 📣
Upper thoracic transverse processes all the way up to the Distal
Attachment
process or spinous process of vertebra
immediately (brevis) or 2 segments
From transverse processes of C4-T12 vertebrae

Supports the cervical vertebrae 📣
Considered part of the intermediate group 📣 attachment ❗️
(longus) superior to vertebra of

Three part muscle named based on superior attachments
SEMISPINALIS CAPITIS
Nerve Supply
Extension ❗️
Posterior rami of spinal nerves

Stabilizes the vertebrae and assists
Superomedial occipital bone
Becomes the roof of the suboccipital triangle ❗️ Main action with local extension and rotary
movements of vertebral column; may

📖
Forms a palpable longitudinal bulge at the back near the
median plane
function as organs of proprioception

SEMISPINALIS CERVICIS
Spinous process of the cervical vertebrae
SEMISPINALIS THORACIS
Spinous process of the thoracic vertebrae
Note: Be specific when naming the semispinalis (ex.
semispinalis cervicis, capitis, or thoracis)

Table 9. OINA of Semispinalis Muscle
Proximal
Attachment
Distal
the C4-T12 vertebrae ❗️
Arises from transverse processes of

Thoracis, cervicis, capitis; fibers run
Attachment superomedially to occipital bone and
spinous processes in thoracic and
cervical regions, spanning 4-6
segments
Nerve Supply
Main action Extension ❗️
Posterior rami of spinal nerves

Extends head and thoracic and Figure 36. Rotatores Muscles [Netter]
cervical regions of vertebral column
and rotates them contralaterally

MULTIFIDUS
Thickest at the lumbosacral area of support
→ Because it has to support the area there
❗️
Come from the transverse process below to a spinous
process 1 or 2 spaces above
Table 10. OINA of Multifidus Muscle
Proximal Arises from posterior sacrum, PSIS of
Attachment ilium, aponeurosis of erector spinae,
sacro-iliac ligaments, mammillary
processes of lumbar vertebrae,
transverse processes of T1-T3,

Distal
articular processes of C4-C7
Thickest in lumbar region ❗️
ANATOMY Deep Back Page 14 of 21
 DEEP INTRINSIC LAYER: MINOR LAYER Aid in lateral flexion of vertebral
Main action column; acting bilaterally, stabilizes
vertebral column
LEVATORES COSTARUM

📋
Serve as connections between the medial portions of
the ribs and spinal column
Table 14. OINA of Levator costarum Muscle
Proximal Tips of transverse processes of C7 and
Attachment T1-T11 vertebrae
Distal Pass inferolaterally and insert on rib
Attachment between tubercle and angle
Posterior rami of C8-T11 spinal
Nerve Supply
nerves
Elevate ribs; assisting respiration;
Main action assist with lateral flexion of vertebral
column
C. SUBOCCIPITAL REGION

Figure 37. Deep intrinsic muscle layer: minor layer [Netter]
Note: These are not part of the back, but still considered
as part of the minor deep layer.

INTERSPINALES

📋
Serve as connections between the spinous processes of
each vertebra

📣
Aids in extension and rotation of the vertebral column
In between spinous processes
Table 12. OINA of Interspinales Muscle
Proximal Superior surfaces of spinous process
Attachment of cervical and lumbar vertebrae
Inferior surface of spinous processes
Distal
of vertebra superior to vertebra of
Attachment
proximal attachment
Nerve Supply Posterior rami of spinal nerves
Aid in extension and rotation of
Main action
vertebral column
INTERTRANSVERSARII
In between transverse processes 📣
📋
Serve as connections between the transverse processes of
each vertebra

📋
Posterior intertransversarii muscles of the neck are Figure 38. Suboccipital Triangle [Netter]
elevators of the ribs A muscle “compartment” deep to the superior part of the
Innervated by both posterior and anterior rami of spinal posterior cervical region, underlying the trapezius,
nerves (exception since ALL deep back muscles are
innervated by the posterior rami of spinal nerves only) ❗ sternocleidomastoid, splenius, and semispinalis
→ Splenius ends up on top of the semispinalis capitis 📣
Table 13. OINA of Intertransversarii Muscle
Proximal Transverse processes of cervical and line 📣
→ Semispinalis capitis is attached to the superior nuchal

Attachment
Distal
lumbar vertebrae
Transverse processes of adjacent suboccipital triangle 📣❗️
▪ Removal of semispinalis capitis exposes the

Pyramidal or triangular in space inferior to the external
Attachment vertebrae
Nerve Supply
❗️
Posterior and anterior rami of spinal
nerves posterior aspect of the C1 and C2 vertebrae 📖
occipital prominence of the head that includes the

ANATOMY Deep Back Page 15 of 21
 SUBOCCIPITAL MUSCLES
Innervated by the posterior rami of C1 or suboccipital

Periosteal branches: Outside of arteries 📣
Sacral area: Iliolumbar, lateral, and medial sacral

📣
nerve
Among the four suboccipital muscles, the obliquus

Nutrient branches 📣
Equatorial branches: Feed deeper into vertebral bodies

attachment to the cranium 📖❗️
capitis inferior is the ONLY capitis muscle with no
vertebral foramen and the structures inside 📣
Spinal branches: From segmental arteries that supply the

When you remove the splenius and semispinalis muscle, BLOOD SUPPLY OF THE BACK
you will reveal the suboccipital muscle Similar to the blood supply of vertebrae
Table 15. OINA of Suboccipital Muscles
Origin Insertion
Table 17. Blood supply to the back muscles ❗️
Border Structure
Rectus capitis Spinous process Lateral part of Cervical Occipital, vertebral, and deep cervical
posterior major of vertebra C2 inferior nuchal arteries
line of occipital Thoracic Posterior intercostal
bone
Lumbar Subcostal and lumbar
Rectus capitis Posterior tubercle Medial part of
Sacral Iliolumbar and lateral sacral
posterior minor of posterior arch inferior nuchal
of vertebra C1 line of occipital B. VENOUS DRAINAGE
(atlas) bone The venous drainage in the back has a lot of networks and
Obliquus Transverse Occipital bone is very rich
capitis superior process of C1 between → Anterior and posterior external vertebral venous
superior plexus
& inferior nuchal
lines Surrounds the entire vertebral column 📣
→ Anterior and posterior internal venous plexus

Obliquus
capitis inferior
Posterior tubercle
of posterior arch
Transverse
process of C1
Plexuses communicate through IV foramina and are
densest on the anterior and posterior sides 📋
of vertebra C2
(axis)
(atlas) Intervertebral veins
→ These are veins going through the vertebral bodies
→ Drain into vertebral, intercostal, lumbar, and lateral
📣
SUBOCCIPITAL TRIANGLE
Filled with loose connective tissue to accommodate the
sacral veins
Basivertebral veins 📋
passage of:
→ Suboccipital nerve (C1) ❗️ → Form within the vertebral bodies
→ Drain into the anterior external and especially the

→ Vertebral artery ❗️
▪ Nerve supply to the suboccipital muscles

▪ Pierces through the posterior atlanto-occipital
anterior internal venous plexuses
Venous drainage is very rich in the back, thus spinal
anesthesia in the region requires the thinnest needle

📣
membrane possible to avoid hemorrhaging into the subarachnoid
▪ Branch of the 1st part of the subclavian artery space
Table 16. Borders of suboccipital triangle ❗️
Aspect of
Structure
Triangle
Superomedial Rectus capitis posterior major
Superolateral Obliquus capitis superior
Inferolateral Obliquus capitis inferior
Floor Posterior atlanto-occipital membrane
and posterior arch of vertebra C1
Roof Semispinalis capitis
Contents Vertebral artery and suboccipital nerve
VI. NEUROVASCULATURE
A. BLOOD SUPPLY Figure 39. Venous drainage of vertebral column [Moore]
C. NERVE SUPPLY
❗️
BLOOD SUPPLY OF THE VERTEBRAE
Blood supply are mainly branches from the aorta Spinal nerves will distribute according to their levels
→ Aorta courses anterior to the vertebral body so it will be Posterior rami
→ Supplies cutaneous and motor innervation of back
column 📋
giving off branches that would supply the vertebral
muscles
Intertransversarii muscle, which is not part of the back
MAJOR CERVICAL ARTERIES muscles but considered to be part of the minor deep layer,
Supplies the cervical areas is innervated by BOTH posterior and anterior rami
Vertebral and ascending cervical arteries
→ Includes the occipital artery from the external carotid,

📋
vertebral artery from the subclavian artery, and deep
cervical artery from the costocervical trunk
MAJOR SEGMENTAL ARTERIES
Thoracic area: Posterior intercostal
Lumbar area: Subcostal and lumbar

ANATOMY Deep Back Page 16 of 21
 b. Multifidus
c. Semispinalis
d. Splenius
9. At which region of the vertebral column is rotation
most restricted?
a. Lumbar
b. Thoracic
c. Cervical
ANSWER KEY
1. B The erector spinae muscles are the chief
extensors of the vertebral column and are
divided into three columns: the iliocostalis forms
the lateral column, the longissimus forms the

2. A
medial column. 📖
intermediate column, and the spinalis forms the

The obliquus capitis inferior is indeed a
Figure 40. Nerves of posterior cervical region [Moore]
D. LYMPHATIC DRAINAGE misnomer because it does not attach to the
skull, despite the name "capitis" suggesting
❗️→ Everything above this point will drain into the Posterior
Iliac crest: Point of reference for the lymphatic drainage
otherwise, as it is only attached to the cervical
vertebrae (C1 and C2).
axillary lymph nodes 3. C The atlantoaxial joint is a pivot joint, allowing
→ Everything below this point will drain into the Inguinal for the rotational movement of the head, which is
crucial for turning the head from side to side.
lymph nodes (drains anteriorly)
Skin and neck lymph drain into cervical nodes 📋 4. B.
False
In order to access the vertebral canal from the
back (posterior approach), you need to go
VII. REVIEW QUESTIONS through the posterior ligaments, including the
1. They are considered as the chief extensors of the supraspinous, interspinous, and ligamentum
vertebral column. flavum. This is done to perform spinal
a. Transversospinalis muscles anesthesia or for taking a sample from the spinal
b. Erector Spinae muscles fluid.
c. Suboccipital muscles 5. A. The transverse ligament primarily maintains the
2. Which of the following structures is considered as a stability of the atlantoaxial joint, allowing for
misnomer? controlled head movement while preventing
a. Obliquus capitis inferior