Anatomy of ankle and foot is described briefly with clinical importance and photos.
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Anatomy of ankle and foot is described briefly with clinical importance and photos.
Dr Junaid Ahmad Consultant Plastic Surgeon is best in Lahore. He offers Foot and Hand Trauma management. Call 03104037071
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Contents
Knee Joint anatomy with Diagrams
Anatomical Components of Knee
Anatomy of Patella
Innervations of the Knee
Knee Movements
Osteoarthritis in the Knee
Management of Disorders in Knee joint
This presentation is the first series of the MR imaging of Knee.
In this presentation MRI anatomy has been discussed. As we all know good knowledge of medical imaging three dimensional anatomy is key for good reporting.
Hope we all get benifitted.
Suggestions are most welcome
Knee Problems and Knee Injuries OverviewKunal Shah
The five most common knee problems are arthritis, tendonitis, bruises, cartilage tears, and damaged ligaments. Knee injuries can be caused by accidents, impact, sudden or awkward movements, and gradual wear and tear of the knee joint.
Acl Reconstruction Surgery In Delhi Dr. Shekhar Srivastav 09971192233DelhiArthroscopy
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To discuss the knee joint: At the end of the presentation we should be able to note the following
The type of joint.
Bones and part of the bone that forms the joints
Type of cartilage covering the articular surface.
Attachment of fibrous capsule.
The attachment or lining of the synovial membrane.
Structures found outside the fibrous capsules (Extracapsular structures).
Structures found within the capsules (Intracapsular structures).
Movement and muscle causing the movement.
Blood and Nerve supply.
Applied Anatomy.
Tom Selleck Health: A Comprehensive Look at the Iconic Actor’s Wellness Journeygreendigital
Tom Selleck, an enduring figure in Hollywood. has captivated audiences for decades with his rugged charm, iconic moustache. and memorable roles in television and film. From his breakout role as Thomas Magnum in Magnum P.I. to his current portrayal of Frank Reagan in Blue Bloods. Selleck's career has spanned over 50 years. But beyond his professional achievements. fans have often been curious about Tom Selleck Health. especially as he has aged in the public eye.
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Introduction
Many have been interested in Tom Selleck health. not only because of his enduring presence on screen but also because of the challenges. and lifestyle choices he has faced and made over the years. This article delves into the various aspects of Tom Selleck health. exploring his fitness regimen, diet, mental health. and the challenges he has encountered as he ages. We'll look at how he maintains his well-being. the health issues he has faced, and his approach to ageing .
Early Life and Career
Childhood and Athletic Beginnings
Tom Selleck was born on January 29, 1945, in Detroit, Michigan, and grew up in Sherman Oaks, California. From an early age, he was involved in sports, particularly basketball. which played a significant role in his physical development. His athletic pursuits continued into college. where he attended the University of Southern California (USC) on a basketball scholarship. This early involvement in sports laid a strong foundation for his physical health and disciplined lifestyle.
Transition to Acting
Selleck's transition from an athlete to an actor came with its physical demands. His first significant role in "Magnum P.I." required him to perform various stunts and maintain a fit appearance. This role, which he played from 1980 to 1988. necessitated a rigorous fitness routine to meet the show's demands. setting the stage for his long-term commitment to health and wellness.
Fitness Regimen
Workout Routine
Tom Selleck health and fitness regimen has evolved. adapting to his changing roles and age. During his "Magnum, P.I." days. Selleck's workouts were intense and focused on building and maintaining muscle mass. His routine included weightlifting, cardiovascular exercises. and specific training for the stunts he performed on the show.
Selleck adjusted his fitness routine as he aged to suit his body's needs. Today, his workouts focus on maintaining flexibility, strength, and cardiovascular health. He incorporates low-impact exercises such as swimming, walking, and light weightlifting. This balanced approach helps him stay fit without putting undue strain on his joints and muscles.
Importance of Flexibility and Mobility
In recent years, Selleck has emphasized the importance of flexibility and mobility in his fitness regimen. Understanding the natural decline in muscle mass and joint flexibility with age. he includes stretching and yoga in his routine. These practices help prevent injuries, improve posture, and maintain mobilit
Ethanol (CH3CH2OH), or beverage alcohol, is a two-carbon alcohol
that is rapidly distributed in the body and brain. Ethanol alters many
neurochemical systems and has rewarding and addictive properties. It
is the oldest recreational drug and likely contributes to more morbidity,
mortality, and public health costs than all illicit drugs combined. The
5th edition of the Diagnostic and Statistical Manual of Mental Disorders
(DSM-5) integrates alcohol abuse and alcohol dependence into a single
disorder called alcohol use disorder (AUD), with mild, moderate,
and severe subclassifications (American Psychiatric Association, 2013).
In the DSM-5, all types of substance abuse and dependence have been
combined into a single substance use disorder (SUD) on a continuum
from mild to severe. A diagnosis of AUD requires that at least two of
the 11 DSM-5 behaviors be present within a 12-month period (mild
AUD: 2–3 criteria; moderate AUD: 4–5 criteria; severe AUD: 6–11 criteria).
The four main behavioral effects of AUD are impaired control over
drinking, negative social consequences, risky use, and altered physiological
effects (tolerance, withdrawal). This chapter presents an overview
of the prevalence and harmful consequences of AUD in the U.S.,
the systemic nature of the disease, neurocircuitry and stages of AUD,
comorbidities, fetal alcohol spectrum disorders, genetic risk factors, and
pharmacotherapies for AUD.
MANAGEMENT OF ATRIOVENTRICULAR CONDUCTION BLOCK.pdfJim Jacob Roy
Cardiac conduction defects can occur due to various causes.
Atrioventricular conduction blocks ( AV blocks ) are classified into 3 types.
This document describes the acute management of AV block.
ARTIFICIAL INTELLIGENCE IN HEALTHCARE.pdfAnujkumaranit
Artificial intelligence (AI) refers to the simulation of human intelligence processes by machines, especially computer systems. It encompasses tasks such as learning, reasoning, problem-solving, perception, and language understanding. AI technologies are revolutionizing various fields, from healthcare to finance, by enabling machines to perform tasks that typically require human intelligence.
Basavarajeeyam is an important text for ayurvedic physician belonging to andhra pradehs. It is a popular compendium in various parts of our country as well as in andhra pradesh. The content of the text was presented in sanskrit and telugu language (Bilingual). One of the most famous book in ayurvedic pharmaceutics and therapeutics. This book contains 25 chapters called as prakaranas. Many rasaoushadis were explained, pioneer of dhatu druti, nadi pareeksha, mutra pareeksha etc. Belongs to the period of 15-16 century. New diseases like upadamsha, phiranga rogas are explained.
These simplified slides by Dr. Sidra Arshad present an overview of the non-respiratory functions of the respiratory tract.
Learning objectives:
1. Enlist the non-respiratory functions of the respiratory tract
2. Briefly explain how these functions are carried out
3. Discuss the significance of dead space
4. Differentiate between minute ventilation and alveolar ventilation
5. Describe the cough and sneeze reflexes
Study Resources:
1. Chapter 39, Guyton and Hall Textbook of Medical Physiology, 14th edition
2. Chapter 34, Ganong’s Review of Medical Physiology, 26th edition
3. Chapter 17, Human Physiology by Lauralee Sherwood, 9th edition
4. Non-respiratory functions of the lungs https://academic.oup.com/bjaed/article/13/3/98/278874
Lung Cancer: Artificial Intelligence, Synergetics, Complex System Analysis, S...Oleg Kshivets
RESULTS: Overall life span (LS) was 2252.1±1742.5 days and cumulative 5-year survival (5YS) reached 73.2%, 10 years – 64.8%, 20 years – 42.5%. 513 LCP lived more than 5 years (LS=3124.6±1525.6 days), 148 LCP – more than 10 years (LS=5054.4±1504.1 days).199 LCP died because of LC (LS=562.7±374.5 days). 5YS of LCP after bi/lobectomies was significantly superior in comparison with LCP after pneumonectomies (78.1% vs.63.7%, P=0.00001 by log-rank test). AT significantly improved 5YS (66.3% vs. 34.8%) (P=0.00000 by log-rank test) only for LCP with N1-2. Cox modeling displayed that 5YS of LCP significantly depended on: phase transition (PT) early-invasive LC in terms of synergetics, PT N0—N12, cell ratio factors (ratio between cancer cells- CC and blood cells subpopulations), G1-3, histology, glucose, AT, blood cell circuit, prothrombin index, heparin tolerance, recalcification time (P=0.000-0.038). Neural networks, genetic algorithm selection and bootstrap simulation revealed relationships between 5YS and PT early-invasive LC (rank=1), PT N0—N12 (rank=2), thrombocytes/CC (3), erythrocytes/CC (4), eosinophils/CC (5), healthy cells/CC (6), lymphocytes/CC (7), segmented neutrophils/CC (8), stick neutrophils/CC (9), monocytes/CC (10); leucocytes/CC (11). Correct prediction of 5YS was 100% by neural networks computing (area under ROC curve=1.0; error=0.0).
CONCLUSIONS: 5YS of LCP after radical procedures significantly depended on: 1) PT early-invasive cancer; 2) PT N0--N12; 3) cell ratio factors; 4) blood cell circuit; 5) biochemical factors; 6) hemostasis system; 7) AT; 8) LC characteristics; 9) LC cell dynamics; 10) surgery type: lobectomy/pneumonectomy; 11) anthropometric data. Optimal diagnosis and treatment strategies for LC are: 1) screening and early detection of LC; 2) availability of experienced thoracic surgeons because of complexity of radical procedures; 3) aggressive en block surgery and adequate lymph node dissection for completeness; 4) precise prediction; 5) adjuvant chemoimmunoradiotherapy for LCP with unfavorable prognosis.
5. MOB TCD
Bones
• The articular surfaces are the
medial and lateral femoral
condyles (the intercondylar notch
in between)
• The medial condyle has a longer
articular surface
• The superior aspect of the medial
and lateral tibial condyles
• The posterior aspect of the patella
9. MOB TCD
Patella
• The patella is controlled by the oblique
portions of the vastus medialis and vastus
lateralis.
• The vastus medialis wastes within 24 hours
after an effusion of the knee
• If the oblique fibers of the vastus medialis
are wasted, the patella tends
to sublux laterally on extension
of the knee. This results in
retropatellar pain
11. MOB TCD
Weak Vastus Medialis Obliquus
• Lower most fibres of vastus medialis
• Partly arise adductor magnus
• Straightens the pull on the quads
tendon and patella
• Controls patella tracking during
flexion extension of the knee
• Fibres atrophy quickly after knee
injury
• 10-15 ml of effusion inhibit VMO
• VMO rehabilitation strength and
timing of contraction
14. Capsule Attachments
•
•
•
•
Quadriceps tendon
The patella
The patellar ligament
Retinacular fibres all form the
anterior part of the capsule
• The patellar ligament is the insertion
of the quadriceps tendon
MOB TCD
15. Patellar Ligament
• Antero-inferiorly is attached to the
tuberosity of the tibia
• On either side the retinacular fibres
pass upwards from the tuberosity in a
V-shaped manner to be attached just
below the articular margin
• The deep infrapatellar bursa and
infrapatellar pad of fat lie posterior to
it, separating it from the tibia
MOB TCD
16. Capsule Attachments
• Laterally, the attachment is just beyond
the articular margin
• Laterally, it is attached above the groove
for the popliteus, below the lateral
epicondyle
• There is a gap in the capsule to allow the
popliteus to emerge
MOB TCD
17. Capsule Attachments
• Posterior
• Superiorly, it is attached just beyond
the articular margin and to the lower
border of the popliteal surface of the
femur, above the intercondylar notch
MOB TCD
18. Capsule Attachments
• Postero-inferiorly, the capsule
is attached to the medial
condyle of the tibia
• By a line running above the
groove for the
semimembranosus tendon
• Below the attachment of the
posterior cruciate ligament
MOB TCD
19. Capsule Attachments
• Medially, the capsule is attached
to the femur just beyond the
articular margin of the condyle
• Below the medial epicondyle
MOB TCD
21. Medial Structures
• Medial ligament
• Pes anserinus consists of:
– Sartorius
– Gracilis
– Semitendinosus
• Tibial inter-tendinous bursa
between them
MOB TCD
22. Medial Collateral Ligament (MCL)
or Tibial Collateral Ligament
• Is attached superiorly to the medial
•
•
•
•
•
•
epicondyle of the femur
It blends with the capsule
Attached to the upper third of the
tibia, as far down as the tibial
tuberosity
It has a superficial and deep portion
The deep portion, which is short,
fuses with the capsule
Attached to the medial meniscus
A bursa usually separates the two
parts
MOB TCD
23. Medial Collateral Ligament (MCL)
or Tibial Collateral Ligament
• The tendons of sartorius, gracilis
•
and semitendinosus cross its
tibial attachment where another
bursa is situated
The anterior part tightens during
the first 70–105°of flexion
MOB TCD
24. MOB TCD
Medial Collateral Ligament (MCL)
• Medial ligament, tightens in
•
•
•
•
extension
And at the extremes of medial and
lateral rotation
A valgus stress will put a strain on
the ligament
If gapping occurs when the knee is
extended, this is due to a tear of
posterior medial part of capsule
If gapping only occurs at 15º flexion,
this is due to tear of medial ligament
26. Posterior Medial Structures
• Semimembranosus into the
groove on posterior aspect of
medial tibial condyle and its
extensions
• Upwards and lateral is oblique
popliteal ligament
• Downwards and lateral forms
fascia covering popliteus
• Downwards and medially fuses
with medial ligament
MOB TCD
27. Oblique Popliteal Ligament
• Oblique popliteal ligament passes
upwards and laterally
• Fuses with the fabella if present
• Capsule above lateral femoral condyle
• Pierced by middle genicular vessels
and nerve
• Posterior division of obturator nerve
• Popliteal artery lies on it
MOB TCD
28. Oblique Popliteal Ligament
• Strengthens the posterior portion of the
capsule and prevents extreme lateral
rotation
• It is an expansion from the
semimembranosus tendon close to its
insertion to the tibia
• Branch from the posterior division of the
obturator nerve, pierces the ligament,
supplies cruciates and articular twig to
knee (referred pain from pelvic peritoneum
to knee)
MOB TCD
31. MOB TCD
Poster Lateral Corner
• Posterior horn of lateral
meniscus
• Arcuate complex
• Popliteus
• Lateral head of
gastrocnemius
32. MOB TCD
Lateral Ligament
• Deep in interval between iliotibial
band and biceps
• Lateral epicondyle of femur
• Midpoint superior surface of
fibula and the styloid process of
the fibula
• It is a cord-like structure that is
separated from the capsule by
the tendon of the popliteus
• Surrounded by biceps
Fabbriciani & Oransky, 1992
33. MOB TCD
Lateral Collateral Ligament (LCL)
• Deep to lateral collateral ligament
• Popliteus
• Inferolateral genicular vessels and
nerve
34. Lateral Collateral Ligament (LCL)
or Fibular Collateral Ligament
• Taut in extension
• 20°flexion, lateral ligament complex
more lax than medial
• Primary lateral restraint to varus
loading
• Arcuate ligament is the edge of
capsule that arches above the
popliteus
MOB TCD
35. Arcuate Ligament
• Passes from the tip of the styloid
process
• Just posterior to the lateral ligament
• Blends origin of the lateral head of
gastrocnemius and oblique popliteal
ligament
• Edge of capsule arches over popliteus
and may give partial origin to popliteus
MOB TCD
36. MOB TCD
Fabella
• Fabella lies at point on the
poster lateral side of knee
• Where multidirectional
collagenous tensile stress
meet
• 8% - 10% osseous
• 90% - 92% cartilagenous
Fabbricani & Oransky, 1992
37. Coronary Ligament
• Connects the periphery of the
menisci to the tibia
• They are the portion of the
capsule that is stressed in rotary
movements of the knee
MOB TCD
38. MOB TCD
Popliteus
• Origin inferior, popliteal surface of
tibia, above the soleal line, fascia of
semimembranosus
• Deep to arcuate popliteal ligament
• Enters capsule
• Crosses lateral surface of lateral
meniscus
• Attached by popliteal-meniscal fibres
which bound hiatus
39. MOB TCD
Popliteus
• Enters hiatus
• Crosses femoral condyle
• Deep to lateral collateral
ligament
• Inserts into anterior part of
groove
• Superior popliteal recess
communicates joint
40. MOB TCD
Popliteus
• Femoral condyles rotate
medially around taut ACL during
the locking mechanism of the
knee
• Popliteus laterally rotates the
femur to unlock the knee so
flexion can occur
41. MOB TCD
Iliotibial Tract
• The iliotibial tract is a thickening of the
deep fascia of the thigh, fascia lata
• The tract is attached to Gerdy’s tubercle on
the anterolateral aspect of the lateral tibial
condyle
• The superficial three quarters of the gluteus
maximus end in a thick tendinous lamina
which is inserted into the iliotibial tract
• The tensor fascia lata is also inserted into
the tract
• Gives origin to the oblique fibres of the
vastus lateralis that help to stabilise the
patella
42. MOB TCD
Iliotibial Tract
• In full knee extension the tract lies
anteriorly to the line of flexion of the
knee,
• As it is free of bony attachments
between the lateral femoral
epicondyle and Gerdy’s tubercle
• It is free to move posteriorly to this
axis on flexion of the knee
Standish & Wood, 1996.
• As the tract crosses the lateral
epicondyle of the femur a bursitis
may develop as the result of a
‘long-leg syndrome’
43. MOB TCD
Iliotibial Tract
• The iliotibial band acts as an
extensor of the knee when the knee
is flexed from 0°to 30°and as a
flexor when the knee is flexed more
than 40°, due to the change in the
transverse axis which occurs at
30–40°flexion.
• The pelvic tilt is a mechanism for
tightening the iliotibial band. The
pull of the band stabilises the knee
in extension, as well as helping to
resist extension and adduction of
the hip of the weight-bearing leg
44. MOB TCD
Movements of the Knee Joint
• Flexion and extension take place
between the femoral condyles
and the upper surface of the
menisci
• Rotation occurs between lower
surface of the menisci and upper
surface of the tibia
45. MOB TCD
Extension Screw Home
• Contraction of the quadriceps results
in extension
• The anterior cruciate becomes taut
• And medial rotation of the femur
occurs around the taut anterior
cruciate to accommodate the longer
surface of the medial condyle
46. Flexion
• Femoral condyles rotate
medially around taut ACL during
the locking mechanism of the
knee
• Popliteus laterally rotates the
femur to unlock the knee
• So flexion can occur
• Then the hamstrings flex the
knee
MOB TCD
49. Anterior and Posterior Cruciates
• Anatomically named by their
tibial attachments
• Clinically femoral are called
lateral
origin
• Covered by synovial membrane
on anterior and on both sides
which is reflected from capsule,
• I.e. oblique popliteal ligament
• Bursa between them on lateral
aspect
anterior
MOB TCD
50. Anterior and Posterior
Cruciates Ligament
• Synovial membrane covers the
anterior and sides of the
cruciates
• Not covered on posterior aspect
MOB TCD
51. Anterior Cruciate
• Anterior cruciate is attached
to anterior aspect of the
superior surface of the tibia
behind
• Anterior horn of medial
meniscus in front of the
anterior horn of the lateral
meniscus
• Passes upwards and
laterally to the posterior
aspect of medial surface of
lateral femoral condyle
MOB TCD
52. Superior Aspect of
Tibial Plateau Menisci
Anterior cruciate
ligament
PCL
Posterior meniscofemoral
ligament
MOB TCD
53. Anterior Cruciate Ligament (ACL)
• Three dimensional fan shaped
• Multiple non-parallel interlacing
collagenous fascicles
MOB TCD
55. Anterior Cruciate Ligament
• Tibial attachment is in anteroposterior axis of tibia
• Femoral attachment is in
longitudinal axis of femur
• Forms 40°with its long axis
• 90°twist of fibres from extension
to flexion
MOB TCD
56. Anterior Cruciate Ligament
• Anteromedial fibres have
the most proximal femoral
attachment
• Contribute to anteromedial
stability
• Intermediate to straight and
anteromedial
• Posterolateral aids in
anteromedial stability
MOB TCD
57. Anterior Cruciate Ligament
• ACL are vertical in
extension
• 90°flexion are horizontal
• PCL are more vertical in
90°flexion
MOB TCD
58. Cruciate
• At 0°of flexion the fibres of the ACL
are more vertical
• At 90°flexion they are in the
horizontal plane
• Fibres of the PCL are more vertical
with flexion and increasing flexion,
> 90°becomes pivot
• PCL is least affective at 30°flexion
Hunziker et al 1992, Covey 2001
MOB TCD
63. Posterior Cruciate
• PCL is the strongest
ligament of the knee
• It is shorter
• More vertical
• Less oblique
• Twice as strong as ACL
• Closely applied to the
centre of rotation of knee
• It is the principal stabiliser
Hunziker et al.,1992
MOB TCD
64. Attachment of PCL
• The tibial attachment of the
PCL was on the sloping
posterior portion of the
tibial intercondylar area
• Anterior to tibial articular
margin
• Blends with periosteum
and capsule
• Extended 11.5-17.3 mm
distal to the tibial plateau
Javadpour & O’Brien, 1992
MOB TCD
66. Posterior Cruciate
• Anatomically the fibres pass
anteriorly and medially and
proximally
• It is attached on the anteroinferior part of the lateral
surface of the medial femoral
condyle
• The area for the PCL is larger
than the ACL
• It expands, more on the apex of
the intercondylar notch than on
the inner wall
Hunziker et al.1992
MOB TCD
67. Posterior Cruciate Ligament
•
•
•
•
•
•
Three functional bands
Names vary
Anterior or anterolateral is larger
Central
Taut in flexion
Posterior or posteromedial taut in
extension
• Posterior oblique bundle
Hunziker et al 1992
MOB TCD
68. Attachment of PCL
•
•
•
•
•
Insertions of the PCL
Passes through four zones
Ligament
Fibrocartilage
Tidemark of mineralised
fibrocartilage
• Bone in less than 1 mm
Cooper & Misol, 1970; Fabbriciani & Oransky, 1992
MOB TCD
69. Posterior Cruciate Ligament
• Posterior oblique bundle
• Most posterior fibres
• Attached to posterosuperior part
of femur
• Posterior medial part on
intercondylar area of tibia
• Longest fibres
• Tense in full extension
Fredrick & O’Brien, 1992; Hunziker et al.,1992
MOB TCD
70. Posterior Cruciate
• Proximal fibres on femur
• Posterior fibres on the tibia are
longest
• Undergo least change
MOB TCD
71. Posterior Cruciate
• The PCL is located near the
longitudinal axis of the knee
• Medial to the centre of the
knee
• Vertical in frontal plane
• 30°to 35°in sagittal
• More horizontal in sagittal
with increased flexion
MOB TCD
72. Posterior Cruciate
• PCL provides 94% of restraint to
posterior displacement of the tibia
• Prevents external rotation of tibia
more at 90°than at 30°
• ACL 86% of restraint to anterior
displacement
MOB TCD
74. Blood Supply of Cruciates
• Posterior cruciate is
supplied by four branches
• Distributed fairly evenly over
its course
• Subcortical vascular
network at bony
attachments
• Don’t contribute much to
ligaments
Sick & Koritke, 1960
MOB TCD
75. Blood Supply of PCL
• Main is middle genicular
artery enters upper third
of PCL
• Synovium surrounding
PCL also supplies the PCL
• Contributions inferior
medial, inferior lateral
genicular arteries via
infrapatellar fat pad
• Periligamentous and intra-ligamentous plexus
• Very little from bony attachment
Arnoczky 1987
MOB TCD
76. Posterior Cruciate Ligament
Nerve Supply
• Branches of tibial and
obturator nerves
• Mechanoreceptors
• Proprioceptive action
MOB TCD
77. Nerve Supply of Cruciates
•
•
•
•
Branches of tibial nerve
Middle genicular nerve
Obturator nerve (post)
Branches of the tibial nerve
enter via the femoral
attachment of each ligament
• Nerve fibres are found with
the vessels in the
intravascular spaces
MOB TCD
78. MOB TCD
Mechanoreceptors
•
•
•
•
•
•
•
•
•
Three types
Found near the femoral attachment
Around periphery
Superficially, but well below the
synovial lining.
Where maximum bending occurs
Ruffini endings
And ones resemble golgi tendon
organs
Paccinian
Proprioceptive function
79. MOB TCD
Mechanoreceptors
• Mechanoreceptors
resembling golgi tendons
• Running parallel to the long
axis of the ligament
• Found near the femoral
attachment
• Around the periphery, where
maximum bending occurs
• Posterior division of obturator
nerve
80. Posterior Cruciate Ligament
Bony Attachment
• There is a gradual change in
stiffness between the flexible
ligamentous tissue and bone
• There is a transitional zone of
fibrocartilage between collagen
and bone
• This helps to prevent the
concentration of stress at the
attachment site
Beynnon, 2000; Hunziker et al.,1992
MOB TCD
81. MOB TCD
Anatomy of Menisci
• Menisci are made of fibro
cartilage
• Wedge shaped on cross
section
• Medial is comma shaped with
the wide portion posteriorly
• Lateral is smaller, two horns
closer together round
• They are intracapsular and
intra synovial
anterior
82. MOB TCD
Anatomy of Menisci
• Anterior to posterior
• Medial, anterior horn is
attached to the intercondylar
area in front of the ACL and
the anterior horn of the
lateral meniscus
• Posterior horn of lateral,
posterior horn of medial and
PCL
• Medial is more fixed
• Lateral more mobile
anterior
83. MOB TCD
Anatomy of Menisci
• Medial is attached to the
deep portion of medial
collateral ligament
• Lateral is separated from
lateral ligament by the
inferolateral genicular
vessels and nerve
• The popliteus, which is
attached to lateral meniscus
• Posterior horn gives origin
to meniscofemoral ligament
84. MOB TCD
Anatomy of Menisci
• Coronary ligaments are the
portion of the capsule
attached to the periphery of
meniscus, which connects it
to the tibia
• Synovial membrane, stops
at the upper border of the
meniscus
• Lines the deep aspect of the
coronary ligament
85. MOB TCD
Anatomy of Menisci
• Blood supply at the
periphery only
• Flexion and extension
takes place at the upper
surface of the menisci
• Rotation occurs between
the lower surface of the
menisci and the tibia
anterior
86. MOB TCD
Function of Menisci
•
•
•
•
•
•
•
•
Shock absorption
Redistributes forces
Spread synovial fluid
Minimal effect on stability
On rotation menisci move with femur
Lateral moves 20 - 24 mm
Medial less mobile 10 -15 mm
Lateral meniscus bears more load
87. MOB TCD
Meniscofemoral Ligaments
• Anterior and posterior arise from
posterior horn of lateral meniscus
• Anterior attached to femur anterior to
PCL
• Posterior attached posterior to PCL
• More variations in posterior
88. MOB TCD
Meniscofemoral Ligaments
• The Anterior meniscofemoral
(Humphrey) is attached to lateral
aspect of the medial femoral condyle in
front of the PCL
• The posterior (Wrisberg) is attached
posterior to the PCL
• The posterior meniscofemoral ligament
is usually present
• Vary in size
90. MOB TCD
Articular Fat Pads
•
•
•
•
•
Increase with age
Compact lobules
With fibro-elastic interlobular septa
Septa well vascularised
Provide firmness, deformability and
elastic recoil
Williams & Warick,1980
91. MOB TCD
Infrapatellar Fat Pad (IFP)
• Superiorly
• Fills the space between the inferior
pole of the patella
• The ligamentum patella and deep
infrapatella bursa
• Attached to intercondylar notch via
ligamentum mucosum
Williams & Warick,1980
92. MOB TCD
Infrapatellar Fat Pad
• Posteriorly
• Covered by synovial
membrane
• Forms alar folds
• Femoral condyles
• Intercondylar notch by
ligamentum mucosum
• Attached to anterior
horns of menisci
• Proximal tibia
Williams & Warick,1980
93. MOB TCD
Infrapatellar Fat Pad
• Blood supply inferior
genicular arteries
• Also supply the lower part
of the ACL from network of
synovial membrane of fat
pad
• Centre of fat pad limited
blood supply
• Lateral arthroscopic
approach to avoid injury
Kohn et al., 1995; Eriksson et al., 1980
94. MOB TCD
Infrapatellar Fat Pad
• Can only expand anteriorly
• Inflammation of IFP
• Bulges on either side of patellar
tendon
• Synovial membrane is compressed
by femoral condyles
• Pain and inflammation
96. Hoffa’s Disease
Fat Pad Impingement
• Hyperextension injury
• Genu recurvatum and tilted inferior
pole of patella
• Tenderness distal to patella
• Beyond margins of the patella
Brukner & Khan, 2000; Garret et al., 2000
MOB TCD
99. MOB TCD
Infrapatellar Fat Pad
• ACL repair with patellar tendon may
result in fibrosis of fat pad and pain
• Delays rehabilitation
• Inflammation of IFP may be process
leading to fibrosis
Murakami et al., 1995
101. MOB TCD
Synovial Membrane
• The synovial membrane is
very extensive
• It lines the inner aspect of
the capsule and the nonarticular structures inside
the capsule, except
posteriorly where it is
carried forwards to cover
the anterior and sides of the
cruciate ligaments
102. MOB TCD
Synovial Membrane
• It covers the infrapatellar pad of fat,
forming the alar folds
• The ligamentum mucosum is attached
to the intercondylar notch at the apex
of the alar fold
• The alar folds increase the surface
area of the synovial membrane via the
infrapatellar pad of fat,
• Which fill the changing spaces during
movement of the joint and help to
redistribute the synovial fluid
103. MOB TCD
Synovial Membrane
• The synovial membrane is
continuous with:
• The suprapatellar bursa which
extends a hand’s breadth
above the patella. This bursa
always appears distended
when there is a haemarthrosis
or traumatic synovitis in the
knee joint
• Many other bursae, e.g.
around the popliteus and under
the medial head of the
gastrocnemius
104. MOB TCD
Plica
• A suprapatellar plica may separate
the suprapatellar bursa from the
synovial membrane of the knee joint
• Plicae folds may also be found on
either side of the patella