The document summarizes the anatomy and biomechanics of the ankle joint. It describes the ankle joint as a synovial hinge joint formed by the distal tibia and fibula articulating with the talus bone. The ankle allows for dorsiflexion and plantarflexion movement through the action of various muscles like the tibialis anterior and gastrocnemius. The document also outlines the ligaments supporting the ankle joint and discusses the kinesiology of ankle motion.
Introduction/joints of knee/minisci/capsule&bursae/ligaments/functions/movements/arthrokinematics/locking&unlocking mechanism/muscles/problem associated with knee/knee arcs.
Introduction/joints of knee/minisci/capsule&bursae/ligaments/functions/movements/arthrokinematics/locking&unlocking mechanism/muscles/problem associated with knee/knee arcs.
Biomwchanics of wrist and hand
- Kinematics and Kinetics of joints including flexion and extension mechanism
-Pathomechanics
- Prehension
-Functional position of wrist
THis PPT will give you knowledge about the principles of shoulder; articulating surface, motions, ligamentous structure and musculature structure that related to shoulder region.
Biomwchanics of wrist and hand
- Kinematics and Kinetics of joints including flexion and extension mechanism
-Pathomechanics
- Prehension
-Functional position of wrist
THis PPT will give you knowledge about the principles of shoulder; articulating surface, motions, ligamentous structure and musculature structure that related to shoulder region.
28,000 ankle sprains occur daily in the US (Kaminski 2013)
Ankle is the 2nd most commonly injured body site. (Ferran 2006)
Ankle sprains are the most common type of ankle injury. (Ferran 2006)
A sprained ankle can happen to athletes and non-athletes,
children and adults.
Inversion injury most common mechanism (Ferran 2006)
Only risk factor is previous ankle sprain (Ferran 2006)
Sex , generalized joint laxity or anatomical foot types are
not risk factors. (Beynnon et al. 2002 )
1. Biomechanics of ankle joint subtalar joint and footSaurab Sharma
Biomechanics of Ankle joint- intended to share the powerpoint with first year undergraduate students at Kathmandu University School of Medical Sciences, Nepal.
USMLE MSK L006 Lower 04 Muscles of leg anatomy medical .pdfAHMED ASHOUR
The muscles of the leg are responsible for various movements, including flexion, extension, inversion, and eversion, as well as providing support during activities such as walking and running.
The muscles of the leg can be categorized into several groups based on their functions.
Understanding the actions and functions of these leg muscles is crucial for assessing and treating conditions affecting the lower extremity, such as injuries, imbalances, or musculoskeletal disorders.
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.
Title: Sense of Smell
Presenter: Dr. Faiza, Assistant Professor of Physiology
Qualifications:
MBBS (Best Graduate, AIMC Lahore)
FCPS Physiology
ICMT, CHPE, DHPE (STMU)
MPH (GC University, Faisalabad)
MBA (Virtual University of Pakistan)
Learning Objectives:
Describe the primary categories of smells and the concept of odor blindness.
Explain the structure and location of the olfactory membrane and mucosa, including the types and roles of cells involved in olfaction.
Describe the pathway and mechanisms of olfactory signal transmission from the olfactory receptors to the brain.
Illustrate the biochemical cascade triggered by odorant binding to olfactory receptors, including the role of G-proteins and second messengers in generating an action potential.
Identify different types of olfactory disorders such as anosmia, hyposmia, hyperosmia, and dysosmia, including their potential causes.
Key Topics:
Olfactory Genes:
3% of the human genome accounts for olfactory genes.
400 genes for odorant receptors.
Olfactory Membrane:
Located in the superior part of the nasal cavity.
Medially: Folds downward along the superior septum.
Laterally: Folds over the superior turbinate and upper surface of the middle turbinate.
Total surface area: 5-10 square centimeters.
Olfactory Mucosa:
Olfactory Cells: Bipolar nerve cells derived from the CNS (100 million), with 4-25 olfactory cilia per cell.
Sustentacular Cells: Produce mucus and maintain ionic and molecular environment.
Basal Cells: Replace worn-out olfactory cells with an average lifespan of 1-2 months.
Bowman’s Gland: Secretes mucus.
Stimulation of Olfactory Cells:
Odorant dissolves in mucus and attaches to receptors on olfactory cilia.
Involves a cascade effect through G-proteins and second messengers, leading to depolarization and action potential generation in the olfactory nerve.
Quality of a Good Odorant:
Small (3-20 Carbon atoms), volatile, water-soluble, and lipid-soluble.
Facilitated by odorant-binding proteins in mucus.
Membrane Potential and Action Potential:
Resting membrane potential: -55mV.
Action potential frequency in the olfactory nerve increases with odorant strength.
Adaptation Towards the Sense of Smell:
Rapid adaptation within the first second, with further slow adaptation.
Psychological adaptation greater than receptor adaptation, involving feedback inhibition from the central nervous system.
Primary Sensations of Smell:
Camphoraceous, Musky, Floral, Pepperminty, Ethereal, Pungent, Putrid.
Odor Detection Threshold:
Examples: Hydrogen sulfide (0.0005 ppm), Methyl-mercaptan (0.002 ppm).
Some toxic substances are odorless at lethal concentrations.
Characteristics of Smell:
Odor blindness for single substances due to lack of appropriate receptor protein.
Behavioral and emotional influences of smell.
Transmission of Olfactory Signals:
From olfactory cells to glomeruli in the olfactory bulb, involving lateral inhibition.
Primitive, less old, and new olfactory systems with different path
These lecture slides, by Dr Sidra Arshad, offer a quick overview of physiological basis of a normal electrocardiogram.
Learning objectives:
1. Define an electrocardiogram (ECG) and electrocardiography
2. Describe how dipoles generated by the heart produce the waveforms of the ECG
3. Describe the components of a normal electrocardiogram of a typical bipolar leads (limb II)
4. Differentiate between intervals and segments
5. Enlist some common indications for obtaining an ECG
Study Resources:
1. Chapter 11, Guyton and Hall Textbook of Medical Physiology, 14th edition
2. Chapter 9, Human Physiology - From Cells to Systems, Lauralee Sherwood, 9th edition
3. Chapter 29, Ganong’s Review of Medical Physiology, 26th edition
4. Electrocardiogram, StatPearls - https://www.ncbi.nlm.nih.gov/books/NBK549803/
5. ECG in Medical Practice by ABM Abdullah, 4th edition
6. ECG Basics, http://www.nataliescasebook.com/tag/e-c-g-basics
263778731218 Abortion Clinic /Pills In Harare ,sisternakatoto
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New Drug Discovery and Development .....NEHA GUPTA
The "New Drug Discovery and Development" process involves the identification, design, testing, and manufacturing of novel pharmaceutical compounds with the aim of introducing new and improved treatments for various medical conditions. This comprehensive endeavor encompasses various stages, including target identification, preclinical studies, clinical trials, regulatory approval, and post-market surveillance. It involves multidisciplinary collaboration among scientists, researchers, clinicians, regulatory experts, and pharmaceutical companies to bring innovative therapies to market and address unmet medical needs.
Knee anatomy and clinical tests 2024.pdfvimalpl1234
This includes all relevant anatomy and clinical tests compiled from standard textbooks, Campbell,netter etc..It is comprehensive and best suited for orthopaedicians and orthopaedic residents.
Acute scrotum is a general term referring to an emergency condition affecting the contents or the wall of the scrotum.
There are a number of conditions that present acutely, predominantly with pain and/or swelling
A careful and detailed history and examination, and in some cases, investigations allow differentiation between these diagnoses. A prompt diagnosis is essential as the patient may require urgent surgical intervention
Testicular torsion refers to twisting of the spermatic cord, causing ischaemia of the testicle.
Testicular torsion results from inadequate fixation of the testis to the tunica vaginalis producing ischemia from reduced arterial inflow and venous outflow obstruction.
The prevalence of testicular torsion in adult patients hospitalized with acute scrotal pain is approximately 25 to 50 percent
Title: Sense of Taste
Presenter: Dr. Faiza, Assistant Professor of Physiology
Qualifications:
MBBS (Best Graduate, AIMC Lahore)
FCPS Physiology
ICMT, CHPE, DHPE (STMU)
MPH (GC University, Faisalabad)
MBA (Virtual University of Pakistan)
Learning Objectives:
Describe the structure and function of taste buds.
Describe the relationship between the taste threshold and taste index of common substances.
Explain the chemical basis and signal transduction of taste perception for each type of primary taste sensation.
Recognize different abnormalities of taste perception and their causes.
Key Topics:
Significance of Taste Sensation:
Differentiation between pleasant and harmful food
Influence on behavior
Selection of food based on metabolic needs
Receptors of Taste:
Taste buds on the tongue
Influence of sense of smell, texture of food, and pain stimulation (e.g., by pepper)
Primary and Secondary Taste Sensations:
Primary taste sensations: Sweet, Sour, Salty, Bitter, Umami
Chemical basis and signal transduction mechanisms for each taste
Taste Threshold and Index:
Taste threshold values for Sweet (sucrose), Salty (NaCl), Sour (HCl), and Bitter (Quinine)
Taste index relationship: Inversely proportional to taste threshold
Taste Blindness:
Inability to taste certain substances, particularly thiourea compounds
Example: Phenylthiocarbamide
Structure and Function of Taste Buds:
Composition: Epithelial cells, Sustentacular/Supporting cells, Taste cells, Basal cells
Features: Taste pores, Taste hairs/microvilli, and Taste nerve fibers
Location of Taste Buds:
Found in papillae of the tongue (Fungiform, Circumvallate, Foliate)
Also present on the palate, tonsillar pillars, epiglottis, and proximal esophagus
Mechanism of Taste Stimulation:
Interaction of taste substances with receptors on microvilli
Signal transduction pathways for Umami, Sweet, Bitter, Sour, and Salty tastes
Taste Sensitivity and Adaptation:
Decrease in sensitivity with age
Rapid adaptation of taste sensation
Role of Saliva in Taste:
Dissolution of tastants to reach receptors
Washing away the stimulus
Taste Preferences and Aversions:
Mechanisms behind taste preference and aversion
Influence of receptors and neural pathways
Impact of Sensory Nerve Damage:
Degeneration of taste buds if the sensory nerve fiber is cut
Abnormalities of Taste Detection:
Conditions: Ageusia, Hypogeusia, Dysgeusia (parageusia)
Causes: Nerve damage, neurological disorders, infections, poor oral hygiene, adverse drug effects, deficiencies, aging, tobacco use, altered neurotransmitter levels
Neurotransmitters and Taste Threshold:
Effects of serotonin (5-HT) and norepinephrine (NE) on taste sensitivity
Supertasters:
25% of the population with heightened sensitivity to taste, especially bitterness
Increased number of fungiform papillae
The prostate is an exocrine gland of the male mammalian reproductive system
It is a walnut-sized gland that forms part of the male reproductive system and is located in front of the rectum and just below the urinary bladder
Function is to store and secrete a clear, slightly alkaline fluid that constitutes 10-30% of the volume of the seminal fluid that along with the spermatozoa, constitutes semen
A healthy human prostate measures (4cm-vertical, by 3cm-horizontal, 2cm ant-post ).
It surrounds the urethra just below the urinary bladder. It has anterior, median, posterior and two lateral lobes
It’s work is regulated by androgens which are responsible for male sex characteristics
Generalised disease of the prostate due to hormonal derangement which leads to non malignant enlargement of the gland (increase in the number of epithelial cells and stromal tissue)to cause compression of the urethra leading to symptoms (LUTS
2. ANKLE JOINT
Ankle-FOOT COMPLEX
The ankle-foot complex is structurally analogues to the wrist-hand complex of
the upper extremity.
The ankle-foot complex must meet the stability and mobility demands.
Stability demands-
1. Providing a stable base of support for the body in a variety of weight bearing
postures without undue muscular activity and energy expenditure.
2. Acting as a lever for effective push-off during gait.
Mobility demands-
1. Dampening of rotations imposed by more proximal joints of LL.
2. Being flexible enough as a shock absorber
3. Permitting the foot to conform to the changing and varied terrain on which foot
is placed.
The ankle and foot meet its requirements
through
28 bones
25 joints.
These include:
1. proximal and distal tibiofibular joints
2. Talo-crural or ankle joint
3. Talocalcaneal or subtalar joint
4. Talonavicular joint
5. Calcaneocuboid joint
6. 5 tarso-metatarsal joints
7. 5 metatarso-phalangeal joints
8. 9 inter-phalangeal joints
The bones of the foot are traditionally
divided into 3 functional segments :
• HIND OR REAR FOOT-posterior
segment composed of talus and
calcaneus
• MID FOOT-middle segment composed
of navicular ,cuboid, 3 cuneiforms
• FOREFOOT-anterior segment composed of metatarsals and phalanges.
3. ANKLE JOINT
The term ankle specifically refers to :
• Talocrural joint-The formation of the mortise (a hole)
by the medial malleoli (Tibia) and lateral malleoli
(fibula) with the talus lying in between them makes
up the talocrural joint.
• The ankle is a synovial Hinge joint with joint capsule
and associated ligaments.
• It is generally considered to have a single oblique axis
with 1°of freedom.
PROXIMAL ARTICULAR STRUCTURE
• The proximal segment of ankle is composed of concave surface of distal tibia
and of tibial and fibular malleoli.
• The structure of distal tibia and the two malleoli is referred to as a MORITSE.
• The mortise of the ankle is adjustable, relying on the proximal and distal
tibio-fibular joints.
PROXIMAL TIBIO-FIBULAR JOINT
• It is a plane synovial joint formed by articulation of
head of fibula with the postero-lateral aspect of
tibia.
• Although facets are flat, a slight convexity of tibial
facet and slight concavity of fibula is predominant.
• Each proximal tibiofibular joint is surrounded by a
joint capsule that is reinforced by anterior and
posterior tibiofibular ligaments.
DISTAL TIBIOFIBULAR JOINT
• It is a syndesmosis or fibrous union.
• It is in between the concave facet of tibia and convex facet of
fibula.
• Tibia and fibula do not come into contact with each other at
this point but are separated by fibro-adipose tissue.
• The ligaments of distal tibio-fibular joint are primarily
responsible for maintaining a stable mortise.
TibiaFibula
<<<Talocrural jointTalus
4. Bony landmark:
Tibia:
1. Medial condyle – on proximal end of tibia, medial
aspect.
2. Tibial tuberosity – on proximal end, anterior aspect just
below patella. (insertion for quadriceps tendon)
3. Tibial spine – “Shin bone” - anterior ridge along tibia.
4. Medial malleolus – large protuberance on medial
aspect of ankle.
5. Tibial plateau
6. Lateral condyle
7. Shaft
Fibula:
1. Head – Move distally and posteriorly
from lateral femoral condyle.
2. Lateral malleolus – Large protuberance
on lateral aspect of ankle.
3. Shaft
4. Styloid process
Tarsals:
1. Calcaneus – heel bone.
2. Naviculr tubercle – On medial border
of foot, large bony prominence.
3. Head of the Talus– Just proximal to navicular tubercle,
especially palpable in eversion.
4. Sustentaculum tali – Located between the head of the
Talus and the medial malleolus.Feels like a small ridge.
5. Peroneal tubercle of the calcaneus – On lateral aspect
of foot just distal to lateral malleolus.
6. Medial tubercle of calcaneus – lies on the medial
plantar surface of the calcaneus (not usually sharp or
distinct unless itis associated with a heel spur.
5. Ligaments (lateral)
Lateral ligament It consists of 3
bands
Anterior talofibular ligament
Posterior talofibular
ligament
Calcaneofibular ligament
Distal articular surface
TALUS
3 Articular Surfaces
• Larger lateral facet-triangular shaped
• Smaller medial facet-comma shaped
• Superior facet- TROCHLEAR
Ligaments (medial)
• Fibrous capsule
• Deltoid or medial ligament- strong triangular
Superficial part
Deep part
Superficial part-
Deep Part
It is also called as Anterior tibio-talar ligament.
Attached to the anterior part of medial surface of talus.
ANTERIOR TIBIONAVICULAR
MIDDLE TIBIOCALCANEAN
POSTERIOR TIBIOTALAR
6. Ankle joint function:
• The primary ankle motion of dorsi-flexion and plantar-flexion occurs around
an oblique axis that causes the foot to move across all 3 planes. AXIS
• In neutral position of the ankle, the joint axis passes approximately through
the fibular malleolus and the body of the talus and through or just below the
tibial malleolus and posteriorly.
• Supination = PF + Adduction + Inversion
• Pronation = DF + Abduction + Eversion
• The distal tibia is twisted laterally compared with its proximal
portion accounting for toe-out position of the foot in normal
standing.
• The axis of angle is considered to be rotated laterally 20°-30°
in the transverse plane and inclined 10° down on the lateral
side.
Talar
rotation(7°
med and 10°
lat rotation)
Abduction-
adduction
Transverse
plane
Vertical axis
Talar
tilt(5°)
Inversion-
eversion
Frontal
plane
Anteroposterior
axis
Dorsiflexion-
plantar flexion
Antero-
posterior plane
Frontal axis
7. ARTHROKINEMATICS
• The shape of the body of talus is complex.
• The trochlea is wider anteriorly than posteriorly.
• The lateral (fibular) facet is substantially larger than the medial (tibial) facet
and its surface is oriented slightly obliquely to that of medial facet.
• This resembles a truncated cone.
• This causes greater displacement of fibular malleolus on lateral facet of talus
than the tibial on medial facet.
• The greater excursion of the lateral malleollus results in the imposition of
motion on the fibula in several directions through the ankle ROM.
• This motion is found to be small in magnitude and variable in direction
among individuals and with different loading conditions.
• This is related to the orientation of the proximal tibiofibular facet,with more
mobility available in those facets that are more vertical.
• It may depend on the tibiofibular ligamentous elasticity.
Dorsiflexion
1. Tibialis anterior
2. Extensor digitorum longus
3. Peroneus longus
4. Peroneus brevis
5. peroneus tertius (usually very close to extensor digitorum longus and often
considered as part of this muscle)
6. extensor halluces Longus (deep to ext. Digitorum longus)
Tibialis Anterior
Origin: Lateral condyle and proximal half to two-thirds of the lateral
surface of the tibial shaft, the adjoining anterior surface of the
interosseous membrane and the intermuscular septum between it and the
extensor digitorum longus.
Insertion: Inferomedial aspect of the medial cuneiform and base of the
first metatarsal.
Action: Inverts and adducts the free foot, assists in plantar flexion.
Prevents excessive pronation of the foot during walking.
Innervation: Deep Peroneal nerve (L4 – 5 )
8. Extensor Digitorum Longus
Origin: Lateral condyle of the tibia, the proximal two-
thirds of the medial surface of the fibula, the adjacent
anterior surface of the interosseous membrane, the
anterior intermuscular septum, and the septum
between it and tibialis anterior.
Insertion: Divides into four slips and inserts at the base
of each of the lateral four proximal phalanges. Each
tendon then divides into three slips: an intermediate
slip which attaches to the base of the middle phalanx,
and two collateral slips which attach to the base of the
distal phalanx.
Action: Extension of the four lateral toes, assists with dorsiflexion of the foot
at the ankle.
Innervation: Deep Peroneal nerve (L5 – S1 )
Peroneus Longus Muscle
Origin: Head and proximal two-thirds of the lateral surface of the
fibula, and the anterior and posterior intermuscular septa of the
leg.
Insertion: Passing behind the lateral malleolus, running obliquely
across the sole of the foot from lateral to medial, and ending on
the
base of the first metatarsal and the medial cuneiform bones
Action: Eversion of the foot at the subtalar joint
Innervation: Superficial Peroneal Nerve (L5, S1)
Peroneus Brevis Muscle
Origin: Distal two-thirds of the lateral surface of the
fibula, and the anterior and posterior intermuscular
septa
Insertion: Tubercle on the base of the lateral aspect of
the fifth metatarsal.
Action: Eversion of the foot at the subtalar joint
Innervation: Superficial Peroneal Nerve (L5, S1)
9. Peroneus Tertius
Origin: Distal third or more of the anterior surface of the fibula, the
adjoining anterior surface of the interosseous membrane and the
anterior intermuscular septum
Insertion: Inserts into the medial part of the dorsal surface of the base
of the fifth metatarsal and usually sends an expansion along the medial
border of the shaft the metatarsal
Action: Assists with dorsiflexion of the foot at the ankle
Innervation: Deep Peroneal (L5, S1)
Extensor Hallucis Longus Muscle
• Origin: Middle half of the medial surface of the
fibula, medial to extensor digitorum longus, and
adjacent anterior surface of the interosseous
membrane
• Insertion: Dorsal aspect of the base of the distal
phalanx of the great toe
• Action: Extension of the great toe, assists with
dorsiflexion of the foot at the ankle.
• Innervation: Deep Peroneal nerve (L5 – S1-2 )
Plantar Flexors
1. Calf muscle (gastrocnemius and soleus)
2. Flexor hallucis longus
3. Flexor digitorum longus
4. Tibialis posterior
5. Plantaris
Gastrocnemius Muscle
Origin: Medial head: the depression at the upper and
posterior part of the medial condyle of the femur and
continuing behind the adductor tubercle to a slightly raised
area on the popliteal surface of the femur, just above the
medial condyle.
Lateral head: area on the lateral surface of the lateral
condyle of the femur and to the lower part of the
corresponding supracondylar line.
Insertion: Receives the tendon of soleus on its deep surface to form the
Achilles tendon to attach to the middle of three facets on the posterior
surface of the calcaneus
10. Action: Plantarflexion of the foot at the ankle, assists with flexion of the leg
at the knee.
Innervation: Tibial nerve S1-2
Soleus
Origin: Posterior surface of the head and proximal quarter of
the shaft of the fibula, spanning over to the soleal line and the
middle third of the medial border of the tibia, and a fibrous
band, which arches over the popliteal vessels and tibial nerve,
between the tibia and fibula
Insertion: Joins with the tendon of the gastrocnemius to form
the tendo calcaneus to attach to the middle of three facets on
the posterior surface of the calcaneus. The muscle is covered
proximally by gastrocnemius and is accessible on both sides.
Actions: Plantarflexion of the foot at the ankle
Innervation: Tibial nerve (S1 – 2 )
Flexor Hallucis Longus
Origin: Distal two-thirds of the posterior surfaces of
the fibula, the adjacent interosseus membrane, the
posterior intermuscular septum, and the lateral part of
the fascia covering tibialis posterior
Insertion: Plantar aspect of the base of the distal
phalanx of the great toe after traveling between the
two sesamoids associated with the first metatarsal
head.
Action: Flexion of the great toe, assists with
plantarflexion of the foot at the ankle.
Innervation: Tibial nerve (L5 – S1-2 )
Flexor Digitorum Longus
Origin: Posterior surface of the tibia, just below the soleal line to within
7 or 8 cm of the distal end of the bone, and to the medial part of the
fascia covering the tibialis posterior
Insertion: Plantar surfaces of the bases of the distal phalanges of the
four lateral toes
Action: Flexion of the four lateral toes, assists with plantarflexion of the
foot at the ankle.
Innervation: Tibial nerve (L5 – S1-2 )
11. Tibialis Posterior
Origin: Proximal two-thirds of the posterior surfaces of the tibia and the
fibula and the interosseus membrane.
Insertion: Passing behind the medial malleolus to attach to the bones
that form the arch of the foot: the navicular, each cuneiform and cuboid
the calcaneus and metatarsals 2,3,4
Action: Inverts and adducts the free foot, assists in plantar flexion.
Prevents excessive pronation of the foot during walking.
Innervation: Tibial nerve (L4 – 5 )
Plantaris
Origin: Lateral supracondylar ridge of the femur above the lateral head of
the gastrocnemius.
Insertion: Medial aspect of the posterior surface of the calcaneus, medial to
the Achilles tendon.
Action: Assists with flexion of the knee. Assist with plantarflexion of the foot
at the ankle
Innervation: Tibial Nerve (S1,2)
Invertors
A- Primary:
1- tibialis anterior
2- tibialis posterior
B- secondary :
1- extensor halluces Longus
2- Flexor digitorum longus
3- Flexor hallucis longus
Evertors
A- Primary:
1- Peroneus longus
2- Peroneus brevis
B- secondary :
1- peroneus tertius
2- Extensor digitorum long
12. Subtalar joint
• The talocalcaneal or subtalar joint is a composite
joint formed by three separate plane articulations
between the talus superiorly and calcaneus
inferiorly.
• Provides a triplanar movement around a single
joint axis.
• Articulations:
posterior talocalcaneal articulations-Largest
concave facet-undersurface of body of talus
convex facet- calcaneus
• Anterior and medial talocalcaneal articulations
Convex facet- Inferior body and neck of talus respectively
Concave facet-calcaneus
• Between the posterior articulation and anterior,middle articulation a bony
tunnel is present formed by a sulcus(concave groove) in the inferior talus and
superior calcaneus.
• This funnel shaped tunnel is called TARSAL CANAL
TARSAL CANAL
Larger end- SINUS TARSI-lies anterior to fibular malleolussmaller end- lies posterior
to the tibial malleolus. And above a bony out cropping on calcaneus is called
SUSTENTACULUM TALI
Posterior articulation has its own capsule
Anterior and middle articulations share a capsule with the talonavicular joint.
Ligaments
• Cervical ligament- strongest
• Interosseus talocalcaneal ligament
1- anterior band
2- posterior band
• Others-
1- Calcaneofibular lig
2- lateral talocalcaneal lig
3- Inferior extensor retinaculum –provides
subtalar support
13. 4- Cervical,interosseus,collaterals-talocalcaneal stability
• Allow pronation/supination and rotation.
• The talus articulates with the calcaneus anteriorly, posteriorly and
medially.
• The axis of rotation runs diagonally from the posterior, lateral, plantar
surface to the anterior, medial, dorsal surface.
• The orientation of this axis makes pronation/supination triplanar with
reference to the cardinal planes.
COMPONENT MOVEMENTS
Tibial Rotation
• The subtalar joint can be likened to the action of a mitered hinge
(Inman and Mann, 1973).
• The orientation of the subtalar joint axis causes the tibia to
internally rotate during pronation and externally rotate during
supination.
• Thus, the tibia internally rotates with pronation or knee flexion and
externally rotates with supination or knee extension.
• It is important that knee flexion and pronation occur in
synchronization (as well as knee-extension and supination).
NON- WT BEARING WT-BEARING
SUPINATION CALCANEAL
INVERSION(VALGUS)
CALCANEAL
INVERSION(VARUS)
CALCANEAL
ADDUCTION
TALAR ABDUCTION
(LATERAL
ROTATION)
CALCANEAL
PLANTAR FLEXION
TALAR
DORSI-FLEXION
TIBIOFIBULAR LAT
ROT
NON-WT BEARING WT-BEARING
PRONATION CALCANEAL
EVERSION(VALGUS)
CALCANEAL
EVERSION(VALGUS)
CALCANEAL
ABDUCTION
TALAR ADDUCTION
(MEDIAL ROT)
CALCANEAL DORSI-
FLEXION
TALAR PLANTAR-
FLEXION
TIBIO-FIBULAR
MEDIAL ROTATION
14. • CLOSED PACKED POSITION:- FULL SUPINATION
• POSITION OF RELATIVE MOBILITY: – PRONATION
Transverse tarsal joint
• The transverse tarsal joint, also called the midtarsal or Chopart joint
It is a compound joint formed by the talonavicular and calcaneocuboid
joints .
• The two joints together present an S-shaped joint line that transects
the foot horizontally, dividing the hindfoot from the midfoot and
forefoot.
• The navicular and the cuboid bones are considered, immobile in the
weight-bearing foot.
Talonavicular joint
• The proximal portion of the talonavicular articulation is formed by the
anterior portion of the head of the talus, and the distal portion of the
articulation, by the concave posterior aspect of the navicular bone.
• A single joint capsule encompasses the talonavicular joint facets and the
anterior and medial facets of the subtalar joint.
Ligaments
• Inferior aspect of the joint capsule-plantar
calcaneo-navicular lig/spring lig
• Medially- deltoid lig
• Laterally-bifurcate lig
15. Calcaneo-cuboid joint
• The calcaneo-cuboid joint is formed proximally by the anterior calcaneus and
distally by the posterior cuboid bone
• The calcaneocuboid articulation has its own capsule that is reinforced by
several important ligaments.
The capsule is reinforced
• Laterally - lateral band of the bifurcate ligament (also known as the
calcaneocuboid ligament)
• Dorsally –dorsal calcaneocuboid ligament,
• Inferiorly -plantar calcaneocuboid (short plantar) and the long plantar
ligaments
Midtarsal Joint
• During pronation, the axes of these two joints are
parallel, this unlocks the joint and creates a
hypermobile foot that can absorb shock.
• During supination the axes are not parallel and this
joint becomes locked allowing efficient transmission
of forces.
• Actually consists of two joints: the calcaneocuboid
on the lateral side and the talonavicular on the
medial side.
Tarsal transverse joint axis
• The transverse joint is considered to have two axis around which the talus
and calcaneus moves on the relatively fixed naviculo-cubiod unit.
1- LONGUTUDINAL AXIS
2- OBLIQUE AXIS
Longitudinal axis-
• Motion around this axis is triplanar producing supinaion /pronation with
coupled components similar to those seen in subtalar joint.
• It approaches a true A-P axis producing inversion and eversion component
predominate.
16. Oblique axis
• This triplanar axis also provides supination/pronation with coupled
component movements of the talus and calcaneus segments moving
together on the navicular and cuboid bones.
• The dorsiflexion/plantarflexion and abduction/adduction components
predominate over inversion/eversion motions.
• Motions about the longitudinal and oblique axes are difficult to separate and
quantify.
• The longitudinal axis of the transverse tarsal joint
• Inclined 15° superiorly from the transverse plane
• Inclined 9° medially from the sagittal plane.
Oblique axis
• This triplanar axis also provides supination/pronation with
coupled component movements of the talus and calcaneus
segments moving together on the navicular and cuboid bones.
• The dorsiflexion/plantarflexion and abduction/adduction
components predominate over inversion/eversion motions.
• Motions about the longitudinal and oblique axes are difficult to
separate and quantify.
• The oblique axis of the transverse tarsal joint .
• Inclined 57° from the sagittal plane
• Inclined 52°superiorly from the transverse plane.
15°
9°
57°
52°
17. TRANSVERSE TARSAL JOINT FUNCTION
• Any weight-bearing subtalar motion includes talar abduction/adduction-
dorsiflexion/plantarflexion that also causes motion at the talonavicular
joint
• calcaneal inversion/eversion that causes motion at the calcaneocuboid joint.
• As the subtalar joint supinates, its linkage to the transverse tarsal joint causes
both the talonavicular joint and the calcaneocuboid joint to begin to supinate
also.(CLOSE PACKED POSITION)
• When the subtalar joint is pronated and loose-packed, the transverse tarsal
joint is also mobile and LOOSE PACKED .
• The transverse tarsal joint is the transitional link between the hindfoot and
the forefoot, serving to
(1)add to the supination/pronation range of the subtalar joint and
(2) compensate the forefoot for hindfoot
position.
• Weight-Bearing Hindfoot Pronation and Transverse Tarsal Joint Motion
In the weight-bearing position, medial rotation of the tibia
for example-pivoting on a fixed foot
• Weight-Bearing Hindfoot Supination and
Transverse Tarsal Joint Motion
• A lateral rotatory force on the leg will create
• subtalar supination in the weight-bearing subtalar joint with a relative
pronation of the transverse tarsal joint (opposite motion of the forefoot
segment) to maintain appropriate
• weight-bearing on a level surface Supination of the subtalar joint, however,
can proceed to only a certain point before the transverse
• tarsal joint also begins to supinate.
18. PRONATION
With pronation occurring at the subtalar joint through medial rotation of the
leg, the transverse tarsal joint is free to
(A) supinate slightly to maintain the relatively fixed position of the forefoot
segment;
(B) pronate slightly as occurs in normal standing; or
(C) supinate substantially to maintain appropriate weight-bearing of the forefoot
segment on uneven terrain
SUPINATION
With supination occurring at the subtalar joint through lateral rotation of the
leg, the transverse tarsal joint has limited ability to pronate to maintain the
relatively fixed position of the forefoot segment
(A) will begin to supinate with a greater range of subtalarsupination and
lateral rotation of the leg
19. (B) or will fully supinate along with a fully supinated subtalar joint and
maximal lateral rotation of the superimposed leg .
TARSOMETATARSAL JOINTS
• The tarsometatarsal TMT joints are plane synovial joints formed by the distal
row of tarsal bones (posteriorly) and the bases of the metatarsals.
• LIGAMENT
Deep transverse metatarsal ligament
• This spans the heads of the metatarsals on the plantar surface and is similar
to that found in the hand.
• Contribute to stability of proximal located TMT joints by preventing excessive
motion and splaying of metatarsal heads.
Axis
• A ray is defined as a functional unit formed by a metatarsal and (for the first
through third rays) its associated cuneiform bone.
• The cuneiform bones are included as parts of the movement units of the
TMT rays because of the small and relatively insignificant amount of motion
occuring at the cuneonavicular joints.
• The axis of the first ray is inclined in such as way that dorsiflexion of the first
ray also includes inversion and adduction, whereas plantarflexion is
accompanied by eversion and abduction.
• The abduction/adduction components normally are minimal.
• Movements of the fifth ray around its axis are more restricted and occur
with the opposite arrangement of components.
• Dorsiflexion is accompanied by eversion and abduction, and
plantarflexion is accompanied
*by inversion and adduction.
• The axis for the third ray nearly coincides with a coronal axis; the
predominant motion, therefore, is dorsiflexion/plantarflexion.
• The axes for the second and fourth rays were not determined
FUNCTION
• In weightbearing,the TMT joints function primarily to augment the function
of the transverse tarsal joint; that is, the TMT joints attempt to regulate
20. position of the metatarsals and phalanges (the forefoot) in relation to the
weight-bearing surface.
SUPINATION TWIST
• When the hind foot pronates substantially in wt-bearing position.
• The TTJ Joint counter acts the forefoot to keep the plantar aspect of the foot
in contact with the ground.
• TMT –medial forefoor will press the ground
lateral foot will lift off the ground
1st and 2nd ray -dorsiflexion
4th and 5th ray-plantarflexion
• the entire forefoot undergoes an inversion rotation around a hypothetical
axis at the second ray.
• PRONATION TWIST
• When the hind foot and TTJ are locked in supination ,the adjustment of
forefoot position will be left entirely to TMT Joints.
• TMT-forefoot medial –lift off the ground
• lateral-press to the ground
1st and 2nd-plantarflex
4th and 5th –dorsiflexion
• Eversion accompanies
Arches
• Needed for traction between the floor & foot’s wt bearing structures.
• Tensed throughout stance phase.
• Compared to a tie rod.
• Plantar plates of mtp resist compressive & tensile forces transferred through
plantar aponeurosis.
• In toe extension- mt heads act as pulleys that pull this fascia– supination.