Fascinating facts of deep fascia

 Fascinating facts of deep fascia

 

Definition:

     a fibrous membrane of variable thickness, devoid of fat,   which invests

• the muscles,
•  the several groups and the individual muscles,
•  the nerves and vessels,
•  various organs and glands
• becomes specialized around the joints to form or strengthen ligaments,

•       and binds all the structures together into a firm compact mass

 

Modification of deep fascia :

1. Aponeurosis
2. Retinaculum
3. Bursa
4. Capsules of joint
5. Sheath around the neurovascular bundle Ex: carotid sheath
6. Septa – intermuscular septum
7. Ligaments
8. Connective tissue around the muscle fibre(endomysium) , muscle bundle(perimysium ) and muscle (epimysium)

 

Deep fascia is well define in

1. Limb
2. Neck

SN: very well define deep fascia is iliotibial tract of fascia lata of thigh 

Deep fascia is absent in

1. Most of the face
2. Anterior Abdominal Wall

      to allow extension of abdominal organs.

3. Ischioanal fossa

General features of deep fascia

1. It acts as a base for superficial fascia
2. It is inelastic and tough
3. It is devoid of fat
4. Histologically it is dense irregular connective tissue
5. It contains variable amount of fibroblasts with the ability to contract known as myofibroblasts
6. It is rich in hyaluronic acid
7. It surrounds the muscles, bones, nerves and blood vessels of body
8. It encloses different muscle groups  and also individual muscle
9. It is rich in  Ruffini’s and pacini’s corpuscles which carry proprioception
10. Lacerations of the deep fascia are easily recognized and should be closed

Importance & functions of the deep fascia

1.       It covers the underlying muscles so it  assists them in their action  by the tension and pressure  it exerts on their surfaces.

2.       From its deep surface, septa pass between muscles. These septa may extend to be attached to the bones and form definite intermuscular septa which divide up the interior of the limbs into compartments.

3.       It is thickened in the palm & sole  to form palmer & planter aponeuroses  which provide protective function to deeper structures.

4.       It is thickened around distal joints (e.g. wrist & ankle) to form strong bands (retinacula)                              which hold the underlying tendons in position.

5.       It is thickened opposite the flexor surfaces of the fingers and toes to form tendon sheathes (fibrous flexor sheath)  which hold the tendon and prevent their bending.

 

Nerve supply of deep fascia Deep fascia

1.       Deep fascia is very sensitive

2.       Its nerve supply and that of subcutaneous periosteum is that of the overlying skin

3.       The nerves to muscles supply the intermuscular septa and deep periosteum

4.       Ruffini, Pacini and rare Golgi Mazzoni corpuscles are also present within  the  deep fascia

 

Histology of deep fascia

Histologically it is dense irregular connective tissue

Mean thickness of fascia 100-200 µm

It is formed by multiple layers of collagen fibre bundle

Each layer is separated by a thin layer of adipocytes.

Description of single layer :

Each layer is formed by collagen fibres and elastic fibres and ground substance is rich in hyaluronic acid . the size of collagen fibre are variable , wavy coarse and parallel with each other . The alignment of collagen fibre bundle differ from layer to layer . all fascial layers contain a variable amount of fibroblasts with the ability to contract known as myofibroblasts . the star shaped cytoplasm of elongated fibroblast are arranged between collagen fibre bundle. Elastic fibre are arranged between collagen bundles. They are short, branch, not arrange in bundle, less orderly manner to form a irregular mesh.

Numerous vessels and small nerve are present in deep fascia. The arrangement of nerves are more around the vessels.

Interesting facts about deep fascia :

1.       All fascia is connective tissue but not all connective tissue is fascia

2.       Fascia mostly made up by non-living material known as extra cellular matrix . it is like the inner ocean of our bodies.

3.       Deep fascia is made up mostly by collagen fibre, one of the most common protein in body

4.       The density and direction  of collagen fibre of deep fascia is depend on the function of the individual 

 

Collagen fibres are curve structure why ?

Nature hates straight lines curve structures not only allow for tension to be absorbed but also distributed and transmitted

The arrangement of collagen fibres are multi directional that allow movement in lots of different directions

Interesting point is collagen fibre is also very adaptable and well lay down more fibres in new direction of strain , if the movement and loading is repeated after enough

 

 

 

Continued movement  leads to continued ability to move and stillness leads to stiffness.

The enemy of deep fascia is extended bouts of stillness. Daily regular movement through a wide range without extensive stretching   is likely to maintain the health and flexibility of fascia .

 

•       An extreme example is that of Amar Bharati a sadhu, who over 40 years ago decided to raise his arm above his head as a tribute to Shiva.

•       Over the years the pain that he first experienced, subsided to numbness.  The collagen fibres surrounding the muscle tissue and the joint will, most probably, have become fibrous and hard.  The effort of holding the arm up will have ceased to be an effort, with the fibres taking over the task of holding the arm in that position.

•       The rest of him keeps doing a good job.  We can see him squatting on the ground demonstrating great flexion ability through his knees, hips and ankles.  It’s a perfect demonstration of how continued movement leads to continued ability to move and how stillness leads to stiffness.

 

 

 

 

 

 

 

 

 

ব্রেস্ট পাম্পের প্রকারভেদ ও বাংলাদেশে কোথায় পাওয়া যায়

 নতুন মায়েদের জন্য বুকের দুধ খাওয়ানোর যাত্রা কে সহজ করার সব থেকে ভাল উপায় হচ্ছে ব্রেস্ট পাম্পের ব্যবহার । এই ভিডিওতে আমাদের বিশেষজ্ঞ ডা. প্রীতি আপনাদের ম্যানুয়াল ব্রেস্ট পাম্প এবং ইলেকট্রিক ব্রেস্ট পাম্পের সঠিক ব্যবহার সম্পর্কে জানাবেন। প্রথম 6 মাস শিশুদের শুধুমাত্র মায়ের দুধ দেওয়া উচিত । কিন্তু যখন তা সম্ভব হয়না, তখন সব থেকে ভাল উপায় হচ্ছে ব্রেস্ট পাম্প ব্যবহার করে বুকের দুধ কে বের করা এবং তাকে সংরক্ষণ করা। বুকের দুধ খাওয়ানোর টিপস এবং বুকের দুধ খাওয়ানোর পণ্যগুলির থেকে আপনি সাহায্য পেতে পারেন ।

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ব্রেস্ট পাম্পের অ্যানাটমি (অংশগুলি)

১. ব্রেস্ট শিল্ড (ফ্ল্যাঞ্জ)

• আকার: বিভিন্ন আকারে ব্রেস্ট শিল্ড পাওয়া যায়, যাতে আরামদায়ক এবং কার্যকর দুধ দোহন নিশ্চিত হয়।

২. পাম্প মেকানিজম (মোটর বা ম্যানুয়াল পাম্প)

• ইলেকট্রিক পাম্প: 

• ম্যানুয়াল পাম্প: 

৩. ক্লেকশন বটল/কন্টেইনার

•  এটি দুধ সংগ্রহের জন্য ব্যবহার করা হয়। 

৪. সাকশন টিউব (বা হোস)

• 
  

৫. ভ্যালভ এবং মেমব্রেন

• 
  

৬. পাওয়ার সোর্স

• ইলেকট্রিক পাম্প: 

• ম্যানুয়াল পাম্প: 

৭. কন্ট্রোল প্যানেল (ইলেকট্রিক পাম্প)

• 
  

৮. অ্যাডাপ্টর এবং বেস (যদি প্রযোজ্য হয়)

• 
  

 

 

Pituitary stalk and infundibulum of pituitary gland

 

What is Pituitary Stalk – it is the narrow connection between the hypothalamus and whole pituitary gland whcih containing hypophyseal portal veins and nerve fibers.

Infundibulum – The broader funnel-shaped structure that includes the pituitary stalk, connecting the posterior part of pituitary gland which connect to the hypothalamus.

Why the Temporomandibular Joint (TMJ) is Peculiar (Unique Features)

 

Why the Temporomandibular Joint (TMJ) is Peculiar (Unique Features)

The temporomandibular joint (TMJ) is one of the most complex and unique joints in the skull . It has several peculiar characteristics that distinguish it from other types of synovial joints.

1. It is a Ginglymoarthrodial Joint which means it is  both a hinge joint (ginglymus) and a gliding joint or arthrodial which allows hinge-like movements (opening and closing the mouth) and gliding movements (protrusion and retraction of the jaw).

2. Presence of an Articular Disc (Biconcave Fibrocartilage Disc)

• TMJ has a fibrocartilaginous disc between the mandibular condyle and temporal bone which  divides the joint into two compartments, allowing smooth movement and shock absorption and  also helps prevent direct bone-to-bone contact, which is rare in synovial joints.

3. Dual Compartment Structure (Two Synovial Cavities)

• The articular disc creates two separate compartments:
• Upper compartment → for gliding movements (translation).
• Lower compartment → for hinge movements (rotation).
• This makes the TMJ function as two joints in one.

4. Bilateral Functioning (One of the Only Paired Joints that Works Together)

• Both left and right TMJs work together simultaneously and dysfunction in one TMJ can affect the other, making TMJ disorders complex.Most joints in  body work independently, but TMJs must function synchronously.

5. Only Movable Joint in the Skull

• The TMJ is  only synovial joint in the skull that allows movement and all other skull joints are fibrous (immovable sutures) except for the ossicles of the ear.

6. Atypical Cartilage Lining (Fibrocartilage Instead of Hyaline Cartilage)

• Most synovial joint’s articular surfaces are lined with hyaline cartilage, but the TMJ is covered by fibrocartilage which  is more resistant to wear and tear, making the TMJ more durable.

7. Unstable Joint with High Susceptibility to Disorders (TMD)

• The mandibular condyle does not fit tightly into the temporal bone, making it prone to dislocation.
• Common disorders include:
• TMJ dislocation (jaw locking).
• Temporomandibular disorder (TMD) (pain, clicking, or popping).
• Bruxism (teeth grinding) leading to TMJ dysfunction.

8. Unique Development (Derived from Two Embryonic Origins)

• The TMJ develops from Meckel’s cartilage (one of the derivatives of first pharyngeal arch) and secondary condylar cartilage.
• Most other joints develop from a single cartilage model, but TMJ has dual embryonic origins : mesenchyme and neural crest

9. Involvement in Speech, Chewing, and Expression

• The TMJ is crucial for mastication (chewing), speech, yawning, and facial expressions and dysfunction can affect eating, talking, and even facial appearance.

10. Unusual Blood and Nerve Supply

• TMJ is richly supplied by sensory nerves (Auriculotemporal nerve from CN V3) which  makes it  very sensitive to pain, that is why TMJ disorders cause significant discomfort.

Summary of Peculiarities of the TMJ

Feature	Why It’s Unique
Ginglymoarthrodial joint	Both hinge and gliding functions
Articular disc present	Divides joint into two compartments, shock absorption
Two synovial cavities	Upper compartment = translation, Lower = rotation
Bilateral function	Both joints move together, unlike most joints
Only movable skull joint	Other skull joints are sutures (immovable)
Fibrocartilage lining	More durable than hyaline cartilage
Prone to disorders	Dislocations, TMD, bruxism, clicking sounds
Unique development	Dual embryonic origin (Meckel’s cartilage + secondary cartilage)
Multifunctional	Involved in chewing, speech, yawning, facial expression
Rich nerve supply	Highly sensitive, easily causes pain

 

Conclusion

TMJ is a highly complex, unique, &  specialized joint that plays a crucial role in daily functions. It unique due to its dual movements, articular disc, fibrocartilage lining, and synchronized bilateral function. However, its structural peculiarities make it vulnerable for dysfunction and disorders (TMD).

Osteology : Coccyx

 Coccyx (Tailbone) The coccyx is the small, triangular bone at base of the vertebral column, formed by the fusion of 3 to 5 coccygeal vertebrae. It acts as an attachment site for muscles, ligaments, and tendons, playing a role in pelvic support and posture.

1. General Features of the Coccyx

Feature	Description
Shape	Small, triangular, and  curved bone
Location	Lower end of the vertebral column, below the sacrum vertebra
Formation	It is formed by the fusion of 3 to 5 coccygeal vertebrae (typically 4)
Curvature	Slightly curves anteriorly (more in males, less in females)
Base	The superior, broader part that articulates with the sacrum vertebra
Apex	The inferior, pointed end that does not articulated with any bone
Cornua (Coccygeal Horns)	Two small projections at the base, connecting with the sacral cornua
Transverse Processes	Small lateral extensions present in the first coccygeal vertebra
Articulation	It articulates with the sacrum at the sacrococcygeal joint
Function	It supports body weight during sitting, attachment site for pelvic muscles and ligaments

 

2. Differences Between Coccygeal Vertebrae

• Co1 (First Coccygeal Vertebra):
• Largest and most developed.
• Has transverse processes and cornua (horn-like projections).
• Articulates with the sacrum.
• Co2 to Co4 (or Co5):
• Become progressively smaller and simpler.
• Lack transverse processes.
• Eventually fuse into a single bony mass.

3. Ligaments and Muscles Attached to the Coccyx

Ligaments:

• Anterior sacrococcygeal ligament – Connects sacrum to coccyx (like the anterior longitudinal ligament of the spine).
• Posterior sacrococcygeal ligament – Similar to the posterior longitudinal ligament.
• Lateral sacrococcygeal ligaments – Stabilize the sacrococcygeal joint.
• Intercoccygeal ligaments – Connect coccygeal vertebrae before they fuse.

Muscles:

• Levator ani (pubococcygeus & iliococcygeus) – it supports pelvic organs.
• Coccygeus muscle – it helps with defecation and pelvic floor stability.
• Gluteus maximus – Partly attaches to the coccyx for hip movement.
• Sphincter ani externus – Controls anal opening.

4. Clinical Importance

 Fracture/Dislocation is common in falls or during childbirth, causing coccydynia (tailbone pain).
 Coccygodynia – Chronic pain due to injury, prolonged sitting, or muscle strain.
 Childbirth Adaptation – The female coccyx is more flexible and moves backward during delivery.
 Vestigial Structure – Considered a remnant of a tail from evolutionary history.