top of page
j.jpg

​Spinal Anatomy in Northampton & Corby

Your Local Experts in Low Back Pain

​Are you struggling with Low Back PAIN and looking for effective, professional treatment? At Team Rehab UK Ltd, our dedicated clinics in Brixworth and Corby offer premium physiotherapy services to help you regain your mobility and live pain-free. With a minimum of 24 years of experience each, our highly skilled chartered physiotherapists are committed to providing personalised care tailored to your specific needs.

Understanding Spinal Anatomy

Introduction to Spinal Anatomy

The spine, also known as the backbone, is a marvel of human anatomy, crucial for maintaining our mobility and supporting a wide range of activities. Comprised of a series of vertebral bones separated by cushioning intervertebral discs, the spine not only provides stability and smooth motion but also serves as a protective passageway for the delicate spinal cord. Muscles, tendons, and ligaments work together to support this structure, while nerves branching out from the spinal cord ensure communication between the brain and the rest of the body.

A healthy spine is essential for overall well-being, enabling us to move freely and comfortably. Whether you're dealing with acute or chronic spinal pain, or seeking the best spinal physiotherapists in Northampton, understanding your spine's anatomy can help you make informed decisions about your care and treatment options.

The Vertebrae: Building Blocks of Your Spine

The human spine is an intricate structure made up of bony segments called vertebrae, which are stacked one on top of the other, extending from the base of the skull to the pelvis. These vertebrae are the fundamental units that collectively form a robust and flexible column, essential for movement, support, and protection of the spinal cord. The design of the vertebrae, in conjunction with intervertebral discs, allows for a balance between stability and flexibility, making it possible to perform a wide range of movements while maintaining the structural integrity necessary to support the body’s weight.

the vertebra in the spine

Vertebral Body: The Core Structure


At the heart of each vertebra is the vertebral body, a cylindrical, thick, and sturdy segment of bone that bears the majority of the body’s weight. When you stand, walk, or engage in any upright activities, it’s the vertebral bodies that carry this load. Each vertebral body also provides a stable platform for the attachment of intervertebral discs, which are positioned between each vertebra to cushion and protect the bones from rubbing against each other. The vertebral body’s large surface area helps distribute pressure evenly across the spine, reducing the risk of injury and degeneration.

Pedicles: The Connecting Bridges


Pedicles are two short, thick, cylindrical projections that extend from the back of the vertebral body. These structures act like bridges, connecting the vertebral body to the rest of the vertebra, specifically the lamina and other posterior elements. The pedicles play a crucial role in the overall strength of the vertebra, forming the sides of the spinal canal and serving as conduits for nerves and blood vessels that supply the spinal structures. By linking the front and back portions of the vertebra, pedicles contribute to the stability and rigidity of the spinal column.

Lamina: The Protective Roof


The laminae are flat, arched sections of bone that complete the posterior portion of each vertebra, forming the roof of the spinal canal. This canal is the central passageway through which the spinal cord and its associated nerves travel, making it one of the most critical components of the spine. The laminae provide essential protection for the spinal cord from external forces, shielding it from injury. Additionally, the laminae serve as attachment points for muscles and ligaments that support and move the spine, further enhancing spinal stability and function.

Spinous Processes: The Visible Landmarks


The spinous processes are the bony projections that extend posteriorly from the point where the two laminae meet. These projections are the most palpable parts of the spine, easily felt along the midline of your back. They serve as key attachment points for muscles and ligaments that facilitate the movement and stabilisation of the spine. For instance, when you bend, twist, or extend your back, the muscles attached to the spinous processes are actively engaged. These processes also provide leverage for muscles that maintain posture and control movement, making them integral to spinal mechanics.

Transverse Processes: Anchors for Muscles and Ligaments


Located at the junction where the pedicles meet the laminae, transverse processes are bony protrusions that extend outward from each side of the vertebra. These processes are critical for the attachment of muscles and ligaments that support the spine and control its movement. Specifically, muscles that control the bending and rotation of the spine attach to the transverse processes, allowing for lateral (side-to-side) movement. The transverse processes also serve as leverage points for these muscles, enabling efficient movement with minimal energy expenditure. Additionally, the transverse processes provide attachment points for ligaments that stabilize the spine, particularly in the thoracic region where they connect to the ribs.

Spinal Canal: The Central Pathway


The spinal canal is the hollow tunnel formed by the stacked vertebrae, running through the centre of each vertebra from the base of the skull to the lower back. This canal houses and protects the spinal cord, a vital component of the central nervous system that carries signals between the brain and the rest of the body. The design of the spinal canal ensures that the spinal cord is safeguarded against external pressures and injuries while still allowing for the necessary flexibility of the spine. The canal’s protective role is crucial because any damage to the spinal cord can lead to significant impairments in sensation, movement, and function.

facet joints in the human spine

Facet Joints: The Spine’s Articulating Surfaces

 

Facet joints are small, paired joints located at the back of each vertebra, where the vertebral arch extends outwards. Each vertebra has two sets of facet joints: the superior facets, which connect to the vertebra above, and the inferior facets, which connect to the vertebra below. These joints are synovial, meaning they are surrounded by a capsule filled with lubricating fluid, allowing for smooth movement. The facet joints guide and limit the spine’s range of motion, preventing excessive twisting and bending that could damage the spinal cord or surrounding structures. They also play a role in stabilising the spine, ensuring that the vertebrae remain properly aligned during movement. 

 

Facet joints are particularly important in the context of spinal health because they are a common source of pain when they become arthritic or inflamed. Conditions such as facet joint syndrome can cause significant discomfort and restrict movement, underscoring the importance of maintaining healthy facet joints through appropriate physical activity and care.

Intervertebral Discs

Intervertebral discs are the unsung heroes of the spine, playing a crucial role in both movement and stability. Positioned between each vertebral body, these discs are flat, rounded structures that act as shock absorbers for the spine. Their unique composition allows them to cushion the vertebrae, distributing pressure and preventing bone-on-bone contact during daily activities like walking, running, lifting, or even sitting.

Annulus Fibrosus: The Structural Support


The intervertebral disc is encased by the annulus fibrosus, a tough, multi-layered ring of fibrous tissue that provides the disc with its structural integrity. This outer layer is composed of concentric sheets of collagen fibers, arranged in a crisscross pattern. This intricate design enables the annulus fibrosus to withstand significant forces, including compression, tension, and torsion, which are encountered during various movements and activities. The primary role of the annulus fibrosus is to contain and protect the inner core of the disc, while also helping to evenly distribute mechanical loads across the spine.

The durability of the annulus fibrosus is critical to spinal health, as any weakening or tearing of these fibers can lead to conditions such as a herniated disc. In such cases, the nucleus pulposus can push through a tear in the annulus fibrosus, potentially compressing nearby spinal nerves and causing pain or neurological symptoms.

Nucleus Pulposus: The Gel-Like Core


At the centre of each intervertebral disc lies the nucleus pulposus, a soft, gel-like core that provides the primary cushioning function of the disc. This inner core is composed of a network of collagen fibers immersed in a semi-fluid matrix, rich in water and proteoglycans. The high water content of the nucleus pulposus allows it to act as a hydraulic cushion, absorbing compressive forces that the spine encounters during activities such as jumping, running, or lifting.

As pressure is applied to the spine, the nucleus pulposus distributes this force outward toward the annulus fibrosus, which then resists the deformation and helps maintain the shape of the disc. This mechanism not only protects the vertebrae from excessive stress but also contributes to the overall flexibility of the spine, enabling smooth, pain-free movement.

However, the nucleus pulposus is not immune to the effects of aging. Over time, the water content within the nucleus can diminish, leading to a reduction in disc height and elasticity. This process, known as disc degeneration, can result in reduced shock absorption, increased pressure on the vertebrae, and the potential for painful conditions such as osteoarthritis or spinal stenosis.

nucleos

The Aging Spine and Disc Degeneration

 

As we age, the intervertebral discs undergo natural wear and tear, which can be accelerated by factors such as repetitive strain, poor posture, or traumatic injury. In the last 15 years we have also become increasing aware of the importance that genetics play in the premature occurrence of this degeneration, with up to 70% actually being accredited to your very own genetics building blocks.

 

The cumulative effect of these factors can lead to disc degeneration, a condition where the discs lose their ability to cushion the spine effectively. Degenerated discs may become thinner and less flexible, leading to increased friction between vertebrae, which can cause pain and stiffness.In some cases, the breakdown of the annulus fibrosus can lead to disc herniation, where the nucleus pulposus bulges out and presses on nearby nerves. This can result in symptoms ranging from localised back pain to radiating pain, numbness, or weakness in the limbs, depending on the location of the herniation.

 

Understanding the role of intervertebral discs and the impact of aging on spinal health underscores the importance of maintaining a strong, flexible spine through regular exercise, proper ergonomics, and seeking timely physiotherapy in Northampton for any back-related issues.

The Spinal Column: Segments of the Spine

The spinal column is not a uniform structure; it is divided into five distinct regions, each with its unique characteristics and functions. These segments work together to provide the spine with its remarkable combination of strength, flexibility, and protection for the spinal cord. Understanding these regions is essential for anyone seeking to comprehend how the spine supports and moves the body, and how different conditions can affect spinal health.

The 5 sections of the human spine

Cervical Spine: The Neck’s Mobility and Support


The cervical spine, or neck region, consists of seven vertebrae, numbered C1 to C7 (C1 nearest skull, and goes down from there). This segment is responsible for supporting the weight of the head, which can be as heavy as a bowling ball, yet requires a range of motion that allows us to nod, turn, and tilt our heads with ease. The first two vertebrae in this region, the atlas (C1) and axis (C2), are specially shaped to facilitate this extensive range of motion. The atlas is a ring-shaped vertebra that supports the skull, while the axis has a peg-like projection (the odontoid process) that acts as a pivot, allowing the head to rotate from side to side.

The Cervical spine and the odontoid peg

The cervical spine’s flexibility makes it susceptible to injuries, such as whiplash, which is common in car accidents. Given its critical role in supporting the head and protecting the spinal cord, any pain or dysfunction in this region should be promptly addressed by a shoulder specialist in Northampton or a physiotherapist in Northampton to prevent further complications.

Thoracic Spine: The Rib Cage Connection


The thoracic spine consists of twelve vertebrae, numbered T1 to T12, extending from the base of the neck to the mid-back. This region is unique in that each thoracic vertebra is connected to a pair of ribs, forming the rib cage that protects vital organs like the heart and lungs. The thoracic spine is less flexible than the cervical or lumbar regions due to its attachment to the rib cage, which provides stability but limits the range of motion.

The thoracic spine’s primary function is to support the upper body and provide a strong anchor point for the ribs, facilitating breathing and protecting the internal organs. While the thoracic spine is less prone to injury compared to other spinal segments, it can still be affected by conditions such as kyphosis (excessive outward curvature) or scoliosis (lateral curvature), which may require specialised care from a physiotherapist in Northampton.

Lumbar Spine: The Powerhouse of the Lower Back


The lumbar spine is located in the lower back and is composed of five larger vertebrae, numbered L1 to L5. This region bears the brunt of the body’s weight and is heavily involved in movements such as bending, lifting, and twisting. The lumbar vertebrae are the largest and strongest in the spinal column, designed to handle significant stress and strain.

Due to its role in weight-bearing and movement, the lumbar spine is particularly susceptible to conditions such as herniated discs, lumbar strain, and sciatica. These conditions can cause significant pain and limit mobility, emphasising the importance of seeking physiotherapy in Northampton for effective treatment and rehabilitation.

Sacrum: The Spine’s Connection to the Pelvis


The sacrum is a triangular-shaped bone located at the base of the spine, formed by the fusion of five sacral vertebrae (S1 to S5) during adolescence and early adulthood. The sacrum is wedged between the two hip bones and forms the back part of the pelvis. This bony structure is vital for transferring the weight of the upper body to the lower limbs and provides stability when standing, walking, or sitting.

The sacrum also has an important role in the body’s structural integrity, as it connects the spine to the pelvis via the sacroiliac joints. Dysfunction in these joints can lead to lower back pain or leg pain, which may be treated effectively through physiotherapy in Northampton.

Coccyx: The Tailbone


The coccyx, commonly referred to as the tailbone, is the small, bony structure at the very base of the spinal column. It is formed by the fusion of four small vertebrae and serves as an attachment point for various muscles, ligaments, and tendons, particularly those associated with the pelvic floor. Although it may seem like a vestigial structure, the coccyx plays a significant role in supporting and stabilising a seated posture.

Injuries to the coccyx, often caused by falls or prolonged sitting on hard surfaces, can lead to coccydynia, a condition characterized by tailbone pain. Treatment for coccyx-related issues can include pain management, physiotherapy, and ergonomic adjustments, often guided by a physiotherapist in Northampton.

the sacrum and the coccyx

Ensuring Optimal Treatment Outcomes

At Team Rehab UK, we emphasise that treatments which are not effective should not continue beyond accepted clinical timescales without further in-depth investigations. We prefer these additional assessments to be conducted by consultant specialists outside our company’s financial interests. This approach ensures we receive an unbiased second opinion, guaranteeing that the care you receive is the most clinically appropriate.

The Spine's Natural Curves: Maintaining Balance and Strength

The adult spine, when viewed from the side, exhibits a natural S-shaped curve that is crucial for its function. This curvature is not just a random design but a sophisticated adaptation that helps the spine absorb shock, maintain balance, and distribute mechanical stress during movement and rest.

The Three Major Curves of the Spine


The spine’s natural curves are categorised into three major regions:

Cervical Lordosis: The cervical spine, which makes up the neck region, has an inward curve known as lordosis. This curve is crucial for supporting the weight of the head and allowing for its wide range of motion. It also helps in maintaining the head's center of gravity directly above the spine, which is essential for balance.

Thoracic Kyphosis: Moving down to the thoracic spine, this region has an outward curve known as kyphosis. The thoracic curve is more pronounced and serves to accommodate and protect the thoracic organs, such as the heart and lungs. The slight outward bend helps to offset the inward curves of the cervical and lumbar regions, maintaining overall spinal balance.

Lumbar Lordosis: The lower back, or lumbar region, has another inward curve similar to the cervical spine. This lumbar lordosis is particularly important for supporting the body's weight, especially during activities such as lifting, bending, and sitting. The curve helps to distribute mechanical stress across the lower back, preventing overload on individual vertebrae and intervertebral discs.

The Importance of Spinal Curves

These natural curves play several key roles:

Shock Absorption: The curves act as natural shock absorbers, helping to distribute and mitigate the forces that the body experiences during activities like walking, running, and jumping. Without these curves, the spine would be more prone to injury from the repetitive impact and compression forces.

Balance and Posture: The S-shaped curve of the spine helps to maintain the body's centre of gravity, enabling efficient and stable posture whether you're standing, sitting, or moving. This alignment ensures that the body remains balanced over the pelvis, reducing the strain on muscles and ligaments.

Strength and Flexibility: The natural curves allow the spine to be both strong and flexible. This flexibility enables a wide range of motion, from bending and twisting to stretching and reaching, while the inherent strength of the curved structure supports the body's weight and dynamic movements.

Spinal Alignment and Deformities

When the natural curves of the spine are exaggerated or diminished, it can lead to postural problems and spinal deformities:

Hyperlordosis and Hyperkyphosis: Excessive inward or outward curvatures, respectively, can lead to conditions like swayback or hunchback, which may cause pain and impair movement.

Scoliosis: Unlike the natural curves, scoliosis is a lateral (sideways) curvature of the spine. It often presents as an S or C-shaped curve when viewed from the back and can result in uneven shoulders, hips, and chronic pain. Early detection and intervention by a physiotherapist in Northampton can help manage scoliosis and prevent its progression.

Maintaining the integrity of these natural curves through regular exercise, proper posture, and timely intervention for any spinal issues is crucial for long-term spinal health.

Muscles of the Spine: Movement and Stability

The muscles surrounding the spine are vital for maintaining posture, enabling movement, and stabilising the vertebral column. These muscles are divided into different groups, each with specific functions that contribute to the spine's overall health and functionality.

Extensors: The Backbone of Posture


The extensor muscles are located at the back of the spine. They include the erector spinae muscles, which run along the length of the spine from the base of the skull to the pelvis. These muscles play a crucial role in helping you stand upright and are heavily involved in movements that require lifting or extending the spine backward.

Function: Extensor muscles are essential for maintaining an upright posture. They counterbalance the forward pull of gravity on the head and upper body, preventing you from slumping forward. These muscles also engage during activities like lifting objects, extending the back, and maintaining stability when standing or sitting.

Importance: Weakness or fatigue in the extensor muscles can lead to poor posture, lower back pain, and an increased risk of spinal injuries. Strengthening these muscles through targeted exercises can help support the spine and reduce the strain on intervertebral discs and ligaments.

Flexors

The flexor muscles are found at the front of the spine and include the abdominal muscles. These muscles are key players in movements that involve bending forward, lifting, and stabilising the spine during various activities.

Function: Flexors work to pull the spine forward, assisting in movements like bending at the waist, curling the body forward, and lifting objects from the ground. The abdominal muscles, in particular, provide essential support for the lower back, helping to maintain the natural lumbar curve and prevent hyperextension.

Importance: Strong flexor muscles, particularly the deep core muscles, are vital for spinal stability. They help to evenly distribute forces across the spine, reducing the risk of injury and ensuring that the spine remains properly aligned during movement. Weak or imbalanced flexors can lead to lower back pain, poor posture, and increased susceptibility to injuries.

Obliques: Twisting and Side Bending


The oblique muscles are located on the sides of the body, running diagonally from the ribs to the pelvis. These muscles are responsible for rotational movements and side bending, contributing to the spine's flexibility and stability.

Function: The obliques engage when you twist your torso or bend sideways. They work in coordination with other muscles to stabilise the spine during dynamic movements, such as reaching across your body or twisting to look behind you.

Importance: Strong oblique muscles enhance the spine's ability to perform complex movements and maintain balance. They also play a role in stabilising the core and preventing excessive rotational forces that could strain the spine. Weak obliques can lead to imbalances in the spine's movement patterns, contributing to pain and dysfunction.

The Consequences of Muscle Weakness or Strain


When the muscles of the spine are weak or strained, the stability of the spine is compromised. This can lead to various issues:

Increased Load on the Spine: Weak muscles fail to support the spine adequately, leading to increased stress on the vertebrae, discs, and ligaments. This can result in conditions such spinal stenosis, facet joint overload and chronic back pain.

Poor Posture: Muscle imbalances can cause poor posture, such as slouching or excessive arching of the lower back. Poor posture not only affects the spine but can also lead to discomfort in other areas of the body, such as the shoulders and neck.

Increased Risk of Injury: Strained or weak muscles are more prone to injury, which can lead to spasms, tears, or chronic pain conditions. Regular strengthening and stretching exercises, often prescribed by a physiotherapist in Northampton, are crucial for maintaining muscle health and preventing injury.

Ligaments: Holding It All Together

Ligaments are strong, fibrous bands of connective tissue that play a crucial role in stabilising the spine by holding the vertebrae in place. These ligaments ensure that the spine maintains its proper alignment and integrity during movement and rest.

Anterior and Posterior Longitudinal Ligaments


The anterior and posterior longitudinal ligaments run along the length of the spinal column, closely adhering to the vertebral bodies and intervertebral discs.
 

  • Anterior Longitudinal Ligament (ALL): This ligament is located on the front (anterior) side of the vertebral bodies. It extends from the base of the skull down to the sacrum. The ALL is particularly thick and strong, and its primary function is to prevent hyperextension of the spine (bending too far backward). By restricting excessive backward movement, the ALL helps protect the intervertebral discs and spinal cord from injury.

 

  • Posterior Longitudinal Ligament (PLL): This ligament runs along the back (posterior) side of the vertebral bodies, within the spinal canal. The PLL is narrower and weaker than the ALL, which makes it less effective at resisting herniation of the intervertebral discs. However, it plays a key role in preventing hyperflexion (bending too far forward) and helps to stabilize the vertebrae during forward bending and flexion movements.


Ligamentum Flavum: The Elastic Connectors


The ligamentum flavum is a series of short, elastic ligaments that connect the laminae of adjacent vertebrae. These ligaments are unique due to their high elastin content, which gives them the ability to stretch and recoil.

Function: The ligamentum flavum helps to maintain the normal curvature of the spine and provides flexibility while stabilising the spinal column. Its elasticity allows it to stretch during movement and recoil to its original position, helping to preserve the alignment of the vertebrae and protecting the spinal cord from sudden movements.

Importance: The ligamentum flavum’s elasticity is crucial for maintaining smooth, coordinated movements of the spine. However, with age or degenerative changes, these ligaments can thicken and lose elasticity, contributing to conditions such as spinal stenosis, where the spinal canal narrows and compresses the spinal cord or nerves.

The Role of Ligaments in Spinal Health


The ligaments of the spine work in concert with muscles and tendons to maintain the spine’s stability and alignment.

 

They act as passive stabilisers, ensuring that the vertebrae remain properly positioned relative to each other during both static and dynamic activities. Damage to these ligaments, whether through injury, overuse, or degeneration, can lead to instability, pain, and a higher risk of spinal injuries. Treatment and rehabilitation for ligament injuries often involve activity modification and physiotherapy in Northampton to restore strength and stability.

Ligaments: Holding It All Together

The spinal cord is a vital part of the central nervous system, serving as the primary communication highway between the brain and the rest of the body. It is a cylindrical structure that extends from the base of the brain (the brainstem) down through the vertebral canal to the lower back.

Structure and Protection


The spinal cord is surrounded and protected by three layers of membranes called meninges:
 

  • Dura Mater: The outermost layer, which is tough and durable, providing a protective shield against external impacts.

 

  • Arachnoid Mater: The middle layer, which is a web-like structure that helps cushion the spinal cord.

 

  • Pia Mater: The innermost layer, which is delicate and adheres closely to the surface of the spinal cord, containing blood vessels that nourish the cord.


Between these layers, particularly in the space between the arachnoid mater and pia mater, is the cerebrospinal fluid (CSF). This fluid serves several critical functions:
 

  • Cushioning: CSF acts as a shock absorber, protecting the spinal cord from injury due to sudden movements or impacts.

 

  • Nourishment: CSF provides essential nutrients to the spinal cord and removes waste products.

 

  • Buoyancy: CSF helps to reduce the weight of the spinal cord, allowing it to float within the spinal canal and reducing pressure on its structures.


Spinal Nerves: The Network of Communication


The spinal cord is the source of 31 pairs of spinal nerves, which branch out from the cord and exit the spinal column through openings between the vertebrae. These nerves are organized into segments that correspond to different regions of the body:

Cervical Nerves (C1-C8): These nerves control signals to the neck, shoulders, arms, and hands.

Thoracic Nerves (T1-T12): These nerves control signals to the chest and upper abdomen.

Lumbar Nerves (L1-L5): These nerves control signals to the lower abdomen, hips, and legs.

Sacral Nerves (S1-S5): These nerves control signals to the pelvis, lower legs, and feet.

Coccygeal Nerve: This single nerve controls a small area around the coccyx (tailbone).

The spinal nerves are responsible for transmitting sensory information from the body to the brain and carrying motor commands from the brain to the muscles. This two-way communication allows for the coordination of movement, sensation, and reflexes.

The Impact of Spinal Cord Injuries


Damage to the spinal cord can have severe and often irreversible consequences, depending on the level and severity of the injury:
 

  • Paralysis: Injuries to the spinal cord can result in loss of movement and sensation below the level of the injury. High-level injuries, such as those in the cervical spine, can lead to quadriplegia (paralysis of all four limbs), while lower injuries may result in paraplegia (paralysis of the lower limbs).

 

  • Loss of Sensation: Damage to the spinal cord can disrupt the transmission of sensory information, leading to numbness, tingling, or complete loss of sensation in affected areas.

 

  • Autonomic Dysfunction: The spinal cord also plays a role in regulating involuntary functions such as breathing, heart rate, and bladder control. Injuries can disrupt these functions, leading to life-threatening complications.


Early intervention and specialised care, often involving specialist neurological physiotherapists are crucial for maximising recovery and improving the quality of life for individuals with spinal cord injuries.

We have included this video animation to help you visualise the anatomy that we, as professionals, often take for granted. At Team Rehab UK, we are dedicated to helping our patients understand the causes of their symptoms, empowering them to effectively manage their condition both during and after their treatment.

Please note that some of our videos may be of American origin and might contain slightly different professional terms or approaches compared to those used in the UK. However, the content remains highly informative and beneficial. You should seek advice form your UK based specialist before trying any advice contained, or inferred, in the video you ensure it complies with UK best practice standards.

Summary

Why Understanding Your Spine Matters
A well-functioning spine is the foundation of a healthy, active lifestyle. Whether you're seeking physiotherapy in Northampton, looking for a sports massage in Northampton, or exploring treatment options for shoulder pain in Northampton, knowing your spine's anatomy can empower you to take charge of your health.

At Team Rehab, our physiotherapists in Northampton specialize in diagnosing and treating spine-related conditions. We work closely with top shoulder specialists in Northampton and are recognized providers for Bupa Northampton and Axa Northampton. Our comprehensive approach to shoulder physiotherapy in Northampton ensures that you receive personalized care tailored to your specific needs.

If you're ready to move past pain and regain your freedom of movement, book a consultation today. And if you know someone who could benefit from this information, please share this page with them—help us spread the word and support others in their journey to better health.

If you are experiencing shoulder pain or suspect you have shoulder impingement, seeking prompt physiotherapy in Northampton can help you manage your symptoms and expedite recovery. Our expert team at Team Rehab uk is dedicated to providing comprehensive shoulder physiotherapy in Northampton. We work closely with shoulder specialists and consultants to deliver tailored treatment plans. Additionally, we are recognised by major insurance providers such as Bupa Northampton and Axa Northampton, ensuring that you receive the best care possible.

If you or someone you know is struggling with shoulder pain in Northampton, don't let it hold you back. Contact us today to schedule an appointment and take the first step towards a pain-free life. Share this information via the links below with friends or family who might benefit from our services or online information, and let's help everyone get back to their best selves.

Other related pages you may find interesting or helpful

If you’d like more information about our features, get in touch today.

WHY WE STAND OUT AT TEAM REHAB UK

Extensive Experience and Expertise

​Our team of physiotherapists boast more than 24 years of hands-on experience each, in treating a wide range of back pain conditions. This extensive experience ensures that you receive the highest standard of care, utilising proven techniques and the latest advancements in physiotherapy.

Tailored Treatment Plans

At Team Rehab UK Ltd, we understand that every patient is unique. Our physiotherapists conduct thorough assessments to develop personalised treatment plans that address the root cause of your back pain. Whether you're suffering from acute discomfort or chronic pain, we have the expertise to help.

Our Commitment to Your Well-Being with Patient-Centered Care

Your health and well-being are our top priorities. We take the time to listen to your concerns, understand your goals, and work collaboratively with you to achieve lasting relief from back pain. Our friendly and supportive team is here to guide you every step of the way.

Ongoing Support and Education

We believe in empowering our patients with the knowledge and tools they need to maintain a healthy spine. Our physiotherapists provide ongoing support and education, helping you prevent future injuries and manage your condition effectively.

Convenient Locations in Brixworth and Corby

Brixworth Clinic

Our main rehabilitation centre in Northampton (Brixworth) was purpose built with the sole aim of providing the best opportunities for our expert team to provide you with the best recovery potential. Open in April 2024, the clinic is conveniently located and easily accessible, offering a welcoming environment where you can receive the highest standard of care. We are committed to making your visit as comfortable and effective as possible.

Corby Clinic

The Corby clinic is a much smaller set up within the Lakeside medical centre but we strive to deliver the same exceptional physiotherapy services, within the confines of the setting, ensuring that high-quality physiotherapy is available to the wider community. Our dedicated team is ready to help you overcome back pain and improve your quality of life.

final gym2 copy.jpg

Our Company Mantra of

Honesty, Quality and Integrity in Physiotherapy Healthcare

guides every aspect of our practice

Still Unsure of Something?

We do our very best to put as much on our website as possible however we appreciate there will still be lots of questions and queries. No problem whatsoever, call us for urgent topics or use our contact form to communicate with one of our experts.

Thanks for submitting!

Chris Heywood Physio Ltd is a company registered in England and Wales. Registered number 12948445. Registered Office: 2 Old Road, Scaldwell, Northants, NN6 9LA

Physio Northampton
Privacy Policy

© COPYRIGHT 2025. ALL RIGHTS RESERVED.

bottom of page