Anatomy, Shoulder and Upper Limb, Axillary Lymph Nodes – StatPearls

Introduction

The axilla is a small anatomical space located between the upper thoracic wall and the arm. The main contents include the brachial plexus, axillary artery and vein, and axillary lymph nodes.[1] Lymph nodes contain a range of immune cells, including lymphocytes and macrophages. These remove damaged cells, foreign material, and microorganisms from the lymphatic fluid before returning it to the venous circulation.[2] The axillary lymph nodes arrange into five groups based on their anatomical relations. Collectively, they drain the wall of the thorax, breast, arm, and upper abdominal wall above the umbilicus. The axillary lymph nodes are of particular clinical significance as they are often the first site of breast cancer metastasis.[3] Axillary node involvement is the single most significant prognostic variable for breast cancer patients.[4] Axillary lymphadenopathy is also associated with hematological malignancies, infection, and various autoimmune etiologies. [5] It is, therefore, crucial to have a thorough understanding of this region.

In this article, we will focus primarily on the axillary lymph nodes respective to their anatomical features, relations, drainage, surgical considerations, and clinical significance.

Structure and Function

The axillary lymph nodes reside in the axillary pad of fat and fall into five groups.[3] Every group of lymph nodes receives lymph from a specified, nearby region.

1. Anterior (pectoral) lymph nodes are along the inferior border of pectoralis minor, near the lateral thoracic vessels. They receive lymph from the breast, skin, and muscles of the supraumbilical anterolateral body wall. They drain into the central and apical nodes.

2. Posterior (subscapular) lymph nodes are located on the posterior wall of the axilla along the inferior border of the subscapularis. They receive lymph from the scapular region, as well as the posterior thoracic wall. They drain into the central and apical nodes.

3. Lateral (humeral) lymph nodes are over the lateral wall of the axilla. They receive lymph from the arm and drain into the central, apical, and deep cervical nodes.

4. Central lymph nodes appear in the base of the axilla. They receive lymph from the anterior, posterior, and lateral groups, and drain to the apical lymph nodes.

5. Apical (terminal) lymph nodes are located deep in the apex of the axilla. They receive lymph from all of the groups mentioned above, in addition to the upper breast. The efferent vessels from the apical group converge to form the subclavian lymphatic trunk. On the left, this drains directly drains into the thoracic duct, and on the right, the subclavian trunk drains into the right venous angle via the right lymphatic duct.[6]

The function of the axillary lymph nodes, like that of the rest of the lymphatic system, is to defend against foreign particles, provide immunity against microorganisms, and return excess interstitial fluid back to the systemic circulation. [2] Lymph enters the lymph node through the afferent lymphatic vessel and subsequently flows through a system of sinuses within the node. The series of sinuses begin with the subcapsular sinus and continues to the cortical sinuses and finally, the medullary sinuses. Lymph then exits the node via the efferent lymphatic vessel.

Structurally a lymph node consists of three basic compartments; a cortex, paracortex, and medulla.[7] There are many types of specialized cells within the lymph node concentrated in these areas.[7] The B cell lymphocytes are classically found in the outer cortex and may form lymphoid follicles, while T cells and dendritic cells are classically present in the paracortex. The medulla contains macrophages, plasma cells, and B cells. Activation of a lymph node leads to the development of germinal centers within lymphoid follicles. These are areas in which mature B cells hypermutate, proliferate, and differentiate, to mount an immune response.[7]

Further, the area in the axilla divides into three levels based on where the lymph nodes are traceable. They are:

Level I: In this level, the lymph nodes are traced inferior and lateral to the pectoralis minor muscleLevel II: The lymph nodes are traced deep to the pectoralis minor muscleLevel III: Lymph nodes here can be traced medial and deep to the medial border of the muscle of pectoralis minor.[8]

Embryology

The axillary lymph nodes, like other components of the lymphatic system, develop from hemangioblastic stem cells. There is a close relationship between the lymphatic and vascular systems in early development.[9] Animal studies suggest that lymphatic sacs arise from primitive veins.[10] This activity may occur around week 5 of gestation in humans. By the end of the embryonic period, six primary lymph sacs form. These are the cisterna chyli, two jugular lymph sacs, two iliac lymph sacs, and a retroperitoneal lymph sac.[11] 

Mesenchymal buds invaginate into these lymphatic sacs but do not penetrate the lymphatic endothelium lining the sacs. The mesenchymal buds are then covered by endothelial cells and enlarge. As a result, the initial lymphatic sac becomes the capsule of the mature lymph node, and the mesenchymal invagination becomes the hilus. The sac lumen also forms the sinuses inside the developing lymph node, while the mesenchymal tissue forms the lobules.[7] Lymph sacs are connected by channels to create a network of lymphatic vessels that join to form the early lymphatic system.

Blood Supply and Lymphatics

Lymph nodes are generally found in close association with blood vessels. The axillary lymph nodes receive their blood supply from the axillary artery, and venous drainage occurs via branches of the axillary vein. Interestingly, it has been shown that stage II breast cancer and above are associated with a significant increase in the number of blood vessels in axillary lymph nodes.[12]

Nerves

Lymph nodes do not contain their nervous supply; however, they are often near many different nerves. For example, the axillary lymph nodes are situated near the cords and branches of the brachial plexus, which innervate the muscles of the upper limb. Anatomically, the brachial plexus divisions become cords at the mid-clavicle, while the branches typically originate at the level of the pectoralis minor muscle.[13] The long thoracic nerve, which originates from C5-7 nerve roots, is also located within the axilla.[14] It is important to be aware of these structures as they are vulnerable to injury during axillary lymph node surgery.[15][16]

Muscles

The axilla is a pyramidal shaped area with five anatomical borders, based mainly on the musculature in this region [1]:

• Medial border: the serratus anterior muscle and the first four ribs.

• Lateral border: coracobrachialis and the short head of the biceps muscle.

• Anterior border: pectoralis major and pectoralis minor muscles

• Posterior border: subscapularis, latissimus dorsi, and teres major muscles 

• Superior border: clavicle, scapula, and the first rib

Physiologic Variants

In total, there are between 20 to 30 axillary lymph nodes, though the exact number varies between individuals. The commonest arrangement of these lymphatic pathways is a single linear chain, then a chain branching into two linear chains, and, least common, is a network configuration.[17] Tracing these lymph nodes becomes still difficult due to the high variation in the quantity of subcutaneous adipose tissue.[18] There is also physiological variation in other axillary structures such as the medial cutaneous nerve of the arm and intercostobrachial nerves.[18] Surgeons need to be aware of these when operating on the axilla to avoid iatrogenic injury.

Surgical Considerations

Patients with suspected breast cancer should have an examination for axillary lymphadenopathy. Those with enlarged lymph nodes may be considered for a sentinel lymph node biopsy (SLNB) and/or axillary lymph node dissection (ALND). The sentinel node is the first lymph node into which a primary tumor drains.[19] The identification of this node allows for prognostication.

If an ALND is performed, there are classically three surgical levels of removal:

• Level I: lateral to the pectoralis minor muscle

• Level II: posterior to the pectoralis minor muscle

• Level III (infraclavicular): medial to the pectoralis minor muscle[20]

There are many possible complications of an ALND for carcinoma of the breast. These usually affect the ipsilateral upper limb and may include numbness (39%), pain (39%), arm swelling (25%), and limitation of arm movement (16%).[21] Arm swelling due to interruption of the lymphatic drainage of the upper limb is also known as lymphedema. In this condition, lymph accumulates in the subcutaneous tissue leading to symptoms such as pain and altered sensation, limb heaviness, and difficulty fitting into clothing.[22] A winged scapula may also be observed postoperatively due to injury to the long thoracic nerve, especially in patients with a low body mass index.[16] This nerve innervates the serratus anterior, which acts to pull the scapula forward.

Despite these complications, ALNDs commonly occur unnecessarily in women without nodal involvement. Some authors, therefore, recommend that the clinician perform an SLNB first to confirm the nodal status of the patient.[23] Importantly, the data shows that there is no change in survival in early-stage breast cancer patients treated with SLNB compared to ALND. [24] SLNB may, therefore, spare many women of the morbidity associated with an axillary dissection.

Clinical Significance

Lymph nodes can enlarge in response to numerous etiologies, including malignancy, infections, and autoimmune disease.[5] Cancer of the lymph nodes can subdivide into primary cancers such as lymphoma, as well as secondary cancers, classically of the breast. Management of these tumors may involve the surgical removal of lymph nodes and/or radiotherapy, both of which can damage the lymphatic drainage system.[25]

Infections can be thought of as local or systemic, or classified according to the causative organism. While a significant proportion of lymphadenopathy occurs as a result of bacterial and viral infections, it is important not to forget parasitic infections. Lymphatic filariasis is said to be one of the leading causes of disfigurement and the second most common reason behind permanent disability in the world.[26] In this condition, filarial worms infiltrate and damage the lymphatic system resulting in significant lymphedema (elephantiasis) of the arms, legs, breasts, or genitals. [27]

It has been noted that axillary lymphadenopathy is usually due to infectious conditions like sarcoidosis, cat scratch disease, Staphylococcal, and Streptococcal skin infections, or malignancies like breast cancer, leukemia, and lymphoma.[5]

In breast cancer cases, it is essential to note the number of lymph nodes involved, as the prognosis is worst (in case of relapse) if four or more axillary lymph nodes are involved.  Thus axillary metastasis is not only a marker of diagnosis but also indicates its aggressive phenotype.[4]  Three factors, being tumor size, young age, and poor histology, are significant predictors of axillary lymph node metastatic grading.[28]

The radiological examination of the axillary group of lymph nodes in the case of breast cancers is possible by the computed tomography (CT) scan and magnetic resonance imagining (MRI) that gives high-resolution images. The ultrasound is good to detect morphological abnormalities such as hilar infiltration, cortical thickening, peripheral vascularization, and destruction of the kidney-shaped appearance. [29] But the most specific results are obtained by ultrasound coupled with the fine-needle aspiration needle biopsy (FNAB).[30]

Other Issues

Below is the staging of carcinoma of the breast, primarily based on the axillary lymph nodes’ involvement.

• Stage O: No involvement of axillary lymph nodes. Few cancer cells are present in breast ductules or lobules.

• Stage 1A: No involvement of axillary lymph nodes. Tumor size in the breast is less than 2 cm.

• Stage 1B: Very few lymph nodes are involved, but their size is less than 2mm (micrometastases). The tumor might or might not be present in the breast. If present, it will be less than 2 cm in size. 

• Stage 2A: 1 to 3 axillary lymph nodes show cancer cells and are larger than 2mm with tumor size in breast less than 2cm. Or the size of the tumor in the breast is less than 5 cm without the involvement of lymph nodes. 

• Stage 2B: 1 to 3 axillary lymph nodes involved with a tumor less than 5 cm. Or the tumor is larger than 5 cm in size with no lymph node involvement.

• Stage 3A: 4 to 9 axillary lymph nodes are seen with a tumor less than 5 cm. Or 1 to 9 axillary lymph nodes are involved with the tumor being bigger than 5 cm.

• Stage 3B: Involvement of up to 9 axillary lymph nodes with tumor involving surrounding muscles and skin of the breast. 

• Stage 3C: Here ten or more axillary lymph nodes are involved with also the involvement of the surrounding lymph nodes (like infraclavicular, internal mammary, or supraclavicular lymph nodes)

• Stage 4: Involvement of almost all axillary lymph nodes with distant metastatic spread to organs like lungs, liver, bone, brain, etc.[31]

Review Questions

• Access free multiple choice questions on this topic.

• Comment on this article.

Figure

Lymph nodes of the arm, Deltoid pectoral glands, Axillary glands, Supratrochlear gland. Contributed by Gray’s anatomy Plates

Figure

Axillary lymph nodes, Deltoideo Pectoral glands, lateral group, Subclavicular group, Central group, Subscapular group, Pectoral group, Cutaneous collecting trunk fro the thoracic wall, Cutaneous collecting trunks, Subareolar plexus, Pectoral group, Mammary (more…)

References

1.

Gordon A, Alsayouri K. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jul 25, 2022. Anatomy, Shoulder and Upper Limb, Axilla. [PubMed: 31613503]

2.

Null M, Arbor TC, Agarwal M. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Mar 6, 2023. Anatomy, Lymphatic System. [PubMed: 30020619]

3.

Khan YS, Sajjad H. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jul 25, 2022. Anatomy, Thorax, Mammary Gland. [PubMed: 31613446]

4.

Jatoi I, Hilsenbeck SG, Clark GM, Osborne CK. Significance of axillary lymph node metastasis in primary breast cancer. J Clin Oncol. 1999 Aug;17(8):2334-40. [PubMed: 10561295]

5.

Mohseni S, Shojaiefard A, Khorgami Z, Alinejad S, Ghorbani A, Ghafouri A. Peripheral lymphadenopathy: approach and diagnostic tools. Iran J Med Sci. 2014 Mar;39(2 Suppl):158-70. [PMC free article: PMC3993046] [PubMed: 24753638]

6.

Capobianco SM, Fahmy MW, Sicari V. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jul 25, 2022. Anatomy, Thorax, Subclavian Veins. [PubMed: 30422480]

7.

Willard-Mack CL. Normal structure, function, and histology of lymph nodes. Toxicol Pathol. 2006;34(5):409-24. [PubMed: 17067937]

8.

Dialani V, James DF, Slanetz PJ. A practical approach to imaging the axilla. Insights Imaging. 2015 Apr;6(2):217-29. [PMC free article: PMC4376818] [PubMed: 25534139]

9.

Bautch VL, Caron KM. Blood and lymphatic vessel formation. Cold Spring Harb Perspect Biol. 2015 Mar 02;7(3):a008268. [PMC free article: PMC4355271] [PubMed: 25731762]

10.

Butler MG, Isogai S, Weinstein BM. Lymphatic development. Birth Defects Res C Embryo Today. 2009 Sep;87(3):222-31. [PMC free article: PMC2755610] [PubMed: 19750516]

11.

Ilahi M, St Lucia K, Ilahi TB. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jul 25, 2022. Anatomy, Thorax, Thoracic Duct. [PubMed: 30020599]

12.

Maiborodin IV, Kozyakov AE, Babayants EV, Krasil’nikov SE. Features of Blood Supply to Axillary Lymph Nodes in Breast Cancer Patients. Bull Exp Biol Med. 2017 May;163(1):82-86. [PubMed: 28580489]

13.

Gasparotti R, Shah L. Brachial and Lumbosacral Plexus and Peripheral Nerves. In: Hodler J, Kubik-Huch RA, von Schulthess GK, editors. Diseases of the Brain, Head and Neck, Spine 2020–2023: Diagnostic Imaging [Internet]. Springer; Cham (CH): Feb 15, 2020. pp. 241–254. [PubMed: 32119244]

14.

Lung K, Lui F. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jul 25, 2022. Anatomy, Thorax, Long Thoracic Nerve. [PubMed: 30571017]

15.

Lucci A, McCall LM, Beitsch PD, Whitworth PW, Reintgen DS, Blumencranz PW, Leitch AM, Saha S, Hunt KK, Giuliano AE., American College of Surgeons Oncology Group. Surgical complications associated with sentinel lymph node dissection (SLND) plus axillary lymph node dissection compared with SLND alone in the American College of Surgeons Oncology Group Trial Z0011. J Clin Oncol. 2007 Aug 20;25(24):3657-63. [PubMed: 17485711]

16.

Belmonte R, Monleon S, Bofill N, Alvarado ML, Espadaler J, Royo I. Long thoracic nerve injury in breast cancer patients treated with axillary lymph node dissection. Support Care Cancer. 2015 Jan;23(1):169-75. [PubMed: 25035064]

17.

Peters AM, Fowler JC, Britton TB, Solanki CK, Ballinger JR, Ravichandran D, Mortimer PS, Purushotham AD. Functional variation in lymph node arrangements within the axilla. Lymphat Res Biol. 2009;7(3):139-44. [PubMed: 19778201]

18.

Soares EW. Anatomical variations of the axilla. Springerplus. 2014;3:306. [PMC free article: PMC4093907] [PubMed: 25045608]

19.

Nieweg OE, Tanis PJ, Kroon BB. The definition of a sentinel node. Ann Surg Oncol. 2001 Jul;8(6):538-41. [PubMed: 11456054]

20.

Rinaldi RM, Sapra A, Bellin LS. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Aug 8, 2022. Breast Lymphatics. [PubMed: 31971733]

21.

Brar P, Jain S, Singh I. Complications of Axillary Lymph Node Dissection in Treatment of Early Breast Cancer: A Comparison of MRM and BCS. Indian J Surg Oncol. 2011 Jun;2(2):126-32. [PMC free article: PMC3244199] [PubMed: 22693405]

22.

Sleigh BC, Manna B. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Apr 19, 2023. Lymphedema. [PubMed: 30725924]

23.

Yen TWF, Laud PW, Pezzin LE, McGinley EL, Wozniak E, Sparapani R, Nattinger AB. Prevalence and Consequences of Axillary Lymph Node Dissection in the Era of Sentinel Lymph Node Biopsy for Breast Cancer. Med Care. 2018 Jan;56(1):78-84. [PMC free article: PMC5725235] [PubMed: 29087982]

24.

Giuliano AE, Ballman K, McCall L, Beitsch P, Whitworth PW, Blumencranz P, Leitch AM, Saha S, Morrow M, Hunt KK. Locoregional Recurrence After Sentinel Lymph Node Dissection With or Without Axillary Dissection in Patients With Sentinel Lymph Node Metastases: Long-term Follow-up From the American College of Surgeons Oncology Group (Alliance) ACOSOG Z0011 Randomized Trial. Ann Surg. 2016 Sep;264(3):413-20. [PMC free article: PMC5070540] [PubMed: 27513155]

25.

Warren LE, Miller CL, Horick N, Skolny MN, Jammallo LS, Sadek BT, Shenouda MN, O’Toole JA, MacDonald SM, Specht MC, Taghian AG. The impact of radiation therapy on the risk of lymphedema after treatment for breast cancer: a prospective cohort study. Int J Radiat Oncol Biol Phys. 2014 Mar 01;88(3):565-71. [PMC free article: PMC3928974] [PubMed: 24411624]

26.

Lourens GB, Ferrell DK. Lymphatic Filariasis. Nurs Clin North Am. 2019 Jun;54(2):181-192. [PubMed: 31027660]

27.

Shenoy RK. Clinical and pathological aspects of filarial lymphedema and its management. Korean J Parasitol. 2008 Sep;46(3):119-25. [PMC free article: PMC2553332] [PubMed: 18830049]

28.

Rivadeneira DE, Simmons RM, Christos PJ, Hanna K, Daly JM, Osborne MP. Predictive factors associated with axillary lymph node metastases in T1a and T1b breast carcinomas: analysis in more than 900 patients. J Am Coll Surg. 2000 Jul;191(1):1-6; discussion 6-8. [PubMed: 10898177]

29.

Maxwell F, de Margerie Mellon C, Bricout M, Cauderlier E, Chapelier M, Albiter M, Bourrier P, Espié M, de Kerviler E, de Bazelaire C. Diagnostic strategy for the assessment of axillary lymph node status in breast cancer. Diagn Interv Imaging. 2015 Oct;96(10):1089-101. [PubMed: 26372221]

30.

Lernevall A. Imaging of axillary lymph nodes. Acta Oncol. 2000;39(3):277-81. [PubMed: 10987221]

31.

Akram M, Iqbal M, Daniyal M, Khan AU. Awareness and current knowledge of breast cancer. Biol Res. 2017 Oct 02;50(1):33. [PMC free article: PMC5625777] [PubMed: 28969709]

Disclosure: Harry Kyriacou declares no relevant financial relationships with ineligible companies.

Disclosure: Yusuf Khan declares no relevant financial relationships with ineligible companies.

Anatomy, Shoulder and Upper Limb, Axillary Lymph Nodes – StatPearls

Introduction

The axilla is a small anatomical space located between the upper thoracic wall and the arm. The main contents include the brachial plexus, axillary artery and vein, and axillary lymph nodes.[1] Lymph nodes contain a range of immune cells, including lymphocytes and macrophages. These remove damaged cells, foreign material, and microorganisms from the lymphatic fluid before returning it to the venous circulation.[2] The axillary lymph nodes arrange into five groups based on their anatomical relations. Collectively, they drain the wall of the thorax, breast, arm, and upper abdominal wall above the umbilicus. The axillary lymph nodes are of particular clinical significance as they are often the first site of breast cancer metastasis.[3] Axillary node involvement is the single most significant prognostic variable for breast cancer patients.[4] Axillary lymphadenopathy is also associated with hematological malignancies, infection, and various autoimmune etiologies.[5] It is, therefore, crucial to have a thorough understanding of this region.

In this article, we will focus primarily on the axillary lymph nodes respective to their anatomical features, relations, drainage, surgical considerations, and clinical significance.

Structure and Function

The axillary lymph nodes reside in the axillary pad of fat and fall into five groups.[3] Every group of lymph nodes receives lymph from a specified, nearby region.

1. Anterior (pectoral) lymph nodes are along the inferior border of pectoralis minor, near the lateral thoracic vessels. They receive lymph from the breast, skin, and muscles of the supraumbilical anterolateral body wall. They drain into the central and apical nodes.

2. Posterior (subscapular) lymph nodes are located on the posterior wall of the axilla along the inferior border of the subscapularis. They receive lymph from the scapular region, as well as the posterior thoracic wall. They drain into the central and apical nodes.

3. Lateral (humeral) lymph nodes are over the lateral wall of the axilla. They receive lymph from the arm and drain into the central, apical, and deep cervical nodes.

4. Central lymph nodes appear in the base of the axilla. They receive lymph from the anterior, posterior, and lateral groups, and drain to the apical lymph nodes.

5. Apical (terminal) lymph nodes are located deep in the apex of the axilla. They receive lymph from all of the groups mentioned above, in addition to the upper breast. The efferent vessels from the apical group converge to form the subclavian lymphatic trunk. On the left, this drains directly drains into the thoracic duct, and on the right, the subclavian trunk drains into the right venous angle via the right lymphatic duct.[6]

The function of the axillary lymph nodes, like that of the rest of the lymphatic system, is to defend against foreign particles, provide immunity against microorganisms, and return excess interstitial fluid back to the systemic circulation.[2] Lymph enters the lymph node through the afferent lymphatic vessel and subsequently flows through a system of sinuses within the node. The series of sinuses begin with the subcapsular sinus and continues to the cortical sinuses and finally, the medullary sinuses. Lymph then exits the node via the efferent lymphatic vessel.

Structurally a lymph node consists of three basic compartments; a cortex, paracortex, and medulla.[7] There are many types of specialized cells within the lymph node concentrated in these areas.[7] The B cell lymphocytes are classically found in the outer cortex and may form lymphoid follicles, while T cells and dendritic cells are classically present in the paracortex. The medulla contains macrophages, plasma cells, and B cells. Activation of a lymph node leads to the development of germinal centers within lymphoid follicles. These are areas in which mature B cells hypermutate, proliferate, and differentiate, to mount an immune response.[7]

Further, the area in the axilla divides into three levels based on where the lymph nodes are traceable. They are:

Level I: In this level, the lymph nodes are traced inferior and lateral to the pectoralis minor muscleLevel II: The lymph nodes are traced deep to the pectoralis minor muscleLevel III: Lymph nodes here can be traced medial and deep to the medial border of the muscle of pectoralis minor.[8]

Embryology

The axillary lymph nodes, like other components of the lymphatic system, develop from hemangioblastic stem cells. There is a close relationship between the lymphatic and vascular systems in early development.[9] Animal studies suggest that lymphatic sacs arise from primitive veins. [10] This activity may occur around week 5 of gestation in humans. By the end of the embryonic period, six primary lymph sacs form. These are the cisterna chyli, two jugular lymph sacs, two iliac lymph sacs, and a retroperitoneal lymph sac.[11] 

Mesenchymal buds invaginate into these lymphatic sacs but do not penetrate the lymphatic endothelium lining the sacs. The mesenchymal buds are then covered by endothelial cells and enlarge. As a result, the initial lymphatic sac becomes the capsule of the mature lymph node, and the mesenchymal invagination becomes the hilus. The sac lumen also forms the sinuses inside the developing lymph node, while the mesenchymal tissue forms the lobules.[7] Lymph sacs are connected by channels to create a network of lymphatic vessels that join to form the early lymphatic system.

Blood Supply and Lymphatics

Lymph nodes are generally found in close association with blood vessels. The axillary lymph nodes receive their blood supply from the axillary artery, and venous drainage occurs via branches of the axillary vein.  Interestingly, it has been shown that stage II breast cancer and above are associated with a significant increase in the number of blood vessels in axillary lymph nodes.[12]

Nerves

Lymph nodes do not contain their nervous supply; however, they are often near many different nerves. For example, the axillary lymph nodes are situated near the cords and branches of the brachial plexus, which innervate the muscles of the upper limb. Anatomically, the brachial plexus divisions become cords at the mid-clavicle, while the branches typically originate at the level of the pectoralis minor muscle.[13] The long thoracic nerve, which originates from C5-7 nerve roots, is also located within the axilla.[14] It is important to be aware of these structures as they are vulnerable to injury during axillary lymph node surgery.[15][16]

Muscles

The axilla is a pyramidal shaped area with five anatomical borders, based mainly on the musculature in this region [1]:

• Medial border: the serratus anterior muscle and the first four ribs.

• Lateral border: coracobrachialis and the short head of the biceps muscle.

• Anterior border: pectoralis major and pectoralis minor muscles

• Posterior border: subscapularis, latissimus dorsi, and teres major muscles 

• Superior border: clavicle, scapula, and the first rib

Physiologic Variants

In total, there are between 20 to 30 axillary lymph nodes, though the exact number varies between individuals. The commonest arrangement of these lymphatic pathways is a single linear chain, then a chain branching into two linear chains, and, least common, is a network configuration.[17] Tracing these lymph nodes becomes still difficult due to the high variation in the quantity of subcutaneous adipose tissue.[18] There is also physiological variation in other axillary structures such as the medial cutaneous nerve of the arm and intercostobrachial nerves.[18] Surgeons need to be aware of these when operating on the axilla to avoid iatrogenic injury.

Surgical Considerations

Patients with suspected breast cancer should have an examination for axillary lymphadenopathy. Those with enlarged lymph nodes may be considered for a sentinel lymph node biopsy (SLNB) and/or axillary lymph node dissection (ALND). The sentinel node is the first lymph node into which a primary tumor drains.[19] The identification of this node allows for prognostication.

If an ALND is performed, there are classically three surgical levels of removal:

• Level I: lateral to the pectoralis minor muscle

• Level II: posterior to the pectoralis minor muscle

• Level III (infraclavicular): medial to the pectoralis minor muscle[20]

There are many possible complications of an ALND for carcinoma of the breast. These usually affect the ipsilateral upper limb and may include numbness (39%), pain (39%), arm swelling (25%), and limitation of arm movement (16%).[21] Arm swelling due to interruption of the lymphatic drainage of the upper limb is also known as lymphedema. In this condition, lymph accumulates in the subcutaneous tissue leading to symptoms such as pain and altered sensation, limb heaviness, and difficulty fitting into clothing.[22] A winged scapula may also be observed postoperatively due to injury to the long thoracic nerve, especially in patients with a low body mass index.[16] This nerve innervates the serratus anterior, which acts to pull the scapula forward.

Despite these complications, ALNDs commonly occur unnecessarily in women without nodal involvement. Some authors, therefore, recommend that the clinician perform an SLNB first to confirm the nodal status of the patient.[23] Importantly, the data shows that there is no change in survival in early-stage breast cancer patients treated with SLNB compared to ALND.[24] SLNB may, therefore, spare many women of the morbidity associated with an axillary dissection.

Clinical Significance

Lymph nodes can enlarge in response to numerous etiologies, including malignancy, infections, and autoimmune disease. [5] Cancer of the lymph nodes can subdivide into primary cancers such as lymphoma, as well as secondary cancers, classically of the breast. Management of these tumors may involve the surgical removal of lymph nodes and/or radiotherapy, both of which can damage the lymphatic drainage system.[25]

Infections can be thought of as local or systemic, or classified according to the causative organism. While a significant proportion of lymphadenopathy occurs as a result of bacterial and viral infections, it is important not to forget parasitic infections. Lymphatic filariasis is said to be one of the leading causes of disfigurement and the second most common reason behind permanent disability in the world.[26] In this condition, filarial worms infiltrate and damage the lymphatic system resulting in significant lymphedema (elephantiasis) of the arms, legs, breasts, or genitals.[27]

It has been noted that axillary lymphadenopathy is usually due to infectious conditions like sarcoidosis, cat scratch disease, Staphylococcal, and Streptococcal skin infections, or malignancies like breast cancer, leukemia, and lymphoma. [5]

In breast cancer cases, it is essential to note the number of lymph nodes involved, as the prognosis is worst (in case of relapse) if four or more axillary lymph nodes are involved.  Thus axillary metastasis is not only a marker of diagnosis but also indicates its aggressive phenotype.[4]  Three factors, being tumor size, young age, and poor histology, are significant predictors of axillary lymph node metastatic grading.[28]

The radiological examination of the axillary group of lymph nodes in the case of breast cancers is possible by the computed tomography (CT) scan and magnetic resonance imagining (MRI) that gives high-resolution images. The ultrasound is good to detect morphological abnormalities such as hilar infiltration, cortical thickening, peripheral vascularization, and destruction of the kidney-shaped appearance.[29] But the most specific results are obtained by ultrasound coupled with the fine-needle aspiration needle biopsy (FNAB).[30]

Other Issues

Below is the staging of carcinoma of the breast, primarily based on the axillary lymph nodes’ involvement.

• Stage O: No involvement of axillary lymph nodes. Few cancer cells are present in breast ductules or lobules.

• Stage 1A: No involvement of axillary lymph nodes. Tumor size in the breast is less than 2 cm.

• Stage 1B: Very few lymph nodes are involved, but their size is less than 2mm (micrometastases). The tumor might or might not be present in the breast. If present, it will be less than 2 cm in size. 

• Stage 2A: 1 to 3 axillary lymph nodes show cancer cells and are larger than 2mm with tumor size in breast less than 2cm. Or the size of the tumor in the breast is less than 5 cm without the involvement of lymph nodes. 

• Stage 2B: 1 to 3 axillary lymph nodes involved with a tumor less than 5 cm. Or the tumor is larger than 5 cm in size with no lymph node involvement.

• Stage 3A: 4 to 9 axillary lymph nodes are seen with a tumor less than 5 cm. Or 1 to 9 axillary lymph nodes are involved with the tumor being bigger than 5 cm.

• Stage 3B: Involvement of up to 9 axillary lymph nodes with tumor involving surrounding muscles and skin of the breast. 

• Stage 3C: Here ten or more axillary lymph nodes are involved with also the involvement of the surrounding lymph nodes (like infraclavicular, internal mammary, or supraclavicular lymph nodes)

• Stage 4: Involvement of almost all axillary lymph nodes with distant metastatic spread to organs like lungs, liver, bone, brain, etc.[31]

Review Questions

• Access free multiple choice questions on this topic.

• Comment on this article.

Figure

Lymph nodes of the arm, Deltoid pectoral glands, Axillary glands, Supratrochlear gland. Contributed by Gray’s anatomy Plates

Figure

Axillary lymph nodes, Deltoideo Pectoral glands, lateral group, Subclavicular group, Central group, Subscapular group, Pectoral group, Cutaneous collecting trunk fro the thoracic wall, Cutaneous collecting trunks, Subareolar plexus, Pectoral group, Mammary (more. ..)

References

1.

Gordon A, Alsayouri K. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jul 25, 2022. Anatomy, Shoulder and Upper Limb, Axilla. [PubMed: 31613503]

2.

Null M, Arbor TC, Agarwal M. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Mar 6, 2023. Anatomy, Lymphatic System. [PubMed: 30020619]

3.

Khan YS, Sajjad H. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jul 25, 2022. Anatomy, Thorax, Mammary Gland. [PubMed: 31613446]

4.

Jatoi I, Hilsenbeck SG, Clark GM, Osborne CK. Significance of axillary lymph node metastasis in primary breast cancer. J Clin Oncol. 1999 Aug;17(8):2334-40. [PubMed: 10561295]

5.

Mohseni S, Shojaiefard A, Khorgami Z, Alinejad S, Ghorbani A, Ghafouri A. Peripheral lymphadenopathy: approach and diagnostic tools. Iran J Med Sci. 2014 Mar;39(2 Suppl):158-70. [PMC free article: PMC3993046] [PubMed: 24753638]

6.

Capobianco SM, Fahmy MW, Sicari V. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jul 25, 2022. Anatomy, Thorax, Subclavian Veins. [PubMed: 30422480]

7.

Willard-Mack CL. Normal structure, function, and histology of lymph nodes. Toxicol Pathol. 2006;34(5):409-24. [PubMed: 17067937]

8.

Dialani V, James DF, Slanetz PJ. A practical approach to imaging the axilla. Insights Imaging. 2015 Apr;6(2):217-29. [PMC free article: PMC4376818] [PubMed: 25534139]

9.

Bautch VL, Caron KM. Blood and lymphatic vessel formation. Cold Spring Harb Perspect Biol. 2015 Mar 02;7(3):a008268. [PMC free article: PMC4355271] [PubMed: 25731762]

10.

Butler MG, Isogai S, Weinstein BM. Lymphatic development. Birth Defects Res C Embryo Today. 2009 Sep;87(3):222-31. [PMC free article: PMC2755610] [PubMed: 19750516]

11.

Ilahi M, St Lucia K, Ilahi TB. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jul 25, 2022. Anatomy, Thorax, Thoracic Duct. [PubMed: 30020599]

12.

Maiborodin IV, Kozyakov AE, Babayants EV, Krasil’nikov SE. Features of Blood Supply to Axillary Lymph Nodes in Breast Cancer Patients. Bull Exp Biol Med. 2017 May;163(1):82-86. [PubMed: 28580489]

13.

Gasparotti R, Shah L. Brachial and Lumbosacral Plexus and Peripheral Nerves. In: Hodler J, Kubik-Huch RA, von Schulthess GK, editors. Diseases of the Brain, Head and Neck, Spine 2020–2023: Diagnostic Imaging [Internet]. Springer; Cham (CH): Feb 15, 2020. pp. 241–254. [PubMed: 32119244]

14.

Lung K, Lui F. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jul 25, 2022. Anatomy, Thorax, Long Thoracic Nerve. [PubMed: 30571017]

15.

Lucci A, McCall LM, Beitsch PD, Whitworth PW, Reintgen DS, Blumencranz PW, Leitch AM, Saha S, Hunt KK, Giuliano AE., American College of Surgeons Oncology Group. Surgical complications associated with sentinel lymph node dissection (SLND) plus axillary lymph node dissection compared with SLND alone in the American College of Surgeons Oncology Group Trial Z0011. J Clin Oncol. 2007 Aug 20;25(24):3657-63. [PubMed: 17485711]

16.

Belmonte R, Monleon S, Bofill N, Alvarado ML, Espadaler J, Royo I. Long thoracic nerve injury in breast cancer patients treated with axillary lymph node dissection. Support Care Cancer. 2015 Jan;23(1):169-75. [PubMed: 25035064]

17.

Peters AM, Fowler JC, Britton TB, Solanki CK, Ballinger JR, Ravichandran D, Mortimer PS, Purushotham AD. Functional variation in lymph node arrangements within the axilla. Lymphat Res Biol. 2009;7(3):139-44. [PubMed: 19778201]

18.

Soares EW. Anatomical variations of the axilla. Springerplus. 2014;3:306. [PMC free article: PMC4093907] [PubMed: 25045608]

19.

Nieweg OE, Tanis PJ, Kroon BB. The definition of a sentinel node. Ann Surg Oncol. 2001 Jul;8(6):538-41. [PubMed: 11456054]

20.

Rinaldi RM, Sapra A, Bellin LS. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Aug 8, 2022. Breast Lymphatics. [PubMed: 31971733]

21.

Brar P, Jain S, Singh I. Complications of Axillary Lymph Node Dissection in Treatment of Early Breast Cancer: A Comparison of MRM and BCS. Indian J Surg Oncol. 2011 Jun;2(2):126-32. [PMC free article: PMC3244199] [PubMed: 22693405]

22.

Sleigh BC, Manna B. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Apr 19, 2023. Lymphedema. [PubMed: 30725924]

23.

Yen TWF, Laud PW, Pezzin LE, McGinley EL, Wozniak E, Sparapani R, Nattinger AB. Prevalence and Consequences of Axillary Lymph Node Dissection in the Era of Sentinel Lymph Node Biopsy for Breast Cancer. Med Care. 2018 Jan;56(1):78-84. [PMC free article: PMC5725235] [PubMed: 29087982]

24.

Giuliano AE, Ballman K, McCall L, Beitsch P, Whitworth PW, Blumencranz P, Leitch AM, Saha S, Morrow M, Hunt KK. Locoregional Recurrence After Sentinel Lymph Node Dissection With or Without Axillary Dissection in Patients With Sentinel Lymph Node Metastases: Long-term Follow-up From the American College of Surgeons Oncology Group (Alliance) ACOSOG Z0011 Randomized Trial. Ann Surg. 2016 Sep;264(3):413-20. [PMC free article: PMC5070540] [PubMed: 27513155]

25.

Warren LE, Miller CL, Horick N, Skolny MN, Jammallo LS, Sadek BT, Shenouda MN, O’Toole JA, MacDonald SM, Specht MC, Taghian AG. The impact of radiation therapy on the risk of lymphedema after treatment for breast cancer: a prospective cohort study. Int J Radiat Oncol Biol Phys. 2014 Mar 01;88(3):565-71. [PMC free article: PMC3928974] [PubMed: 24411624]

26.

Lourens GB, Ferrell DK. Lymphatic Filariasis. Nurs Clin North Am. 2019 Jun;54(2):181-192. [PubMed: 31027660]

27.

Shenoy RK. Clinical and pathological aspects of filarial lymphedema and its management. Korean J Parasitol. 2008 Sep;46(3):119-25. [PMC free article: PMC2553332] [PubMed: 18830049]

28.

Rivadeneira DE, Simmons RM, Christos PJ, Hanna K, Daly JM, Osborne MP. Predictive factors associated with axillary lymph node metastases in T1a and T1b breast carcinomas: analysis in more than 900 patients. J Am Coll Surg. 2000 Jul;191(1):1-6; discussion 6-8. [PubMed: 10898177]

29.

Maxwell F, de Margerie Mellon C, Bricout M, Cauderlier E, Chapelier M, Albiter M, Bourrier P, Espié M, de Kerviler E, de Bazelaire C. Diagnostic strategy for the assessment of axillary lymph node status in breast cancer. Diagn Interv Imaging. 2015 Oct;96(10):1089-101. [PubMed: 26372221]

30.

Lernevall A. Imaging of axillary lymph nodes. Acta Oncol. 2000;39(3):277-81. [PubMed: 10987221]

31.

Akram M, Iqbal M, Daniyal M, Khan AU. Awareness and current knowledge of breast cancer. Biol Res. 2017 Oct 02;50(1):33. [PMC free article: PMC5625777] [PubMed: 28969709]

Disclosure: Harry Kyriacou declares no relevant financial relationships with ineligible companies.

Disclosure: Yusuf Khan declares no relevant financial relationships with ineligible companies.

Damage to the lymph nodes in breast cancer, diagnosis, treatment

Why is the lymphatic system needed in the human body?

It is of great importance for the functioning and health of the body. Its tasks: protection from infectious agents, their blocking. The lymphatic system works together with the circulatory system, being an “assistant” for the transportation, processing and removal of unnecessary substances.

Thus, the main role of the lymphatic fluid is the role of a kind of barrier on the way of infectious microorganisms. The lymph nodes act as these barriers. A variety of foreign bodies and microorganisms, getting from the vessels to the lymph nodes, are filtered and destroyed. The lymph fluid that leaves the node captures antibodies and lymphocytes. Please note that together with the lymphatic fluid, in addition to microbes, tumor cells that come out of a malignant neoplasm can also move through the vessels. It is for this reason that, during the cancerous process, the lymph nodes are the first to be hit – tumor cells are found in them.

The axillary lymph nodes are the first group of lymph nodes that react to breast cancer. It is for this reason that if there is even the slightest suspicion of breast cancer, the doctor should evaluate the condition of all axillary lymph nodes. This is of great importance for the prognosis of the disease and the choice of therapeutic measures.

Often, surgical oncologists excise lymph nodes affected by a malignant tumor. The essence of such surgical intervention is to prevent the spread of tumor cells to other tissues and organs. When the lymph nodes involved in the process are excised, the likelihood of the cancer process spreading throughout the body is significantly reduced.

What should be suspected of lymph node involvement?

The appearance of tumor cells in the lymph nodes is evidenced by their marked increase.

In such situations, the oncologist-mammologist prescribes a biopsy of the lymph nodes, since this technique directly allows a reliable assessment of their condition. In the vast majority of cases, lymphatic fluid from the chest area flows into the lymph nodes in the following directions:

• Outflow to the lymph nodes inside the skin in the groin and stomach.

• Cross path: to the lymph nodes in the armpits of the opposite side.

• Outflow of lymphatic fluid into the region behind the pectoral muscles.

• To the parasternal lymph nodes – from the inner quadrants of the breast.

• In the subclavian and then in the supraclavicular lymph nodes from the upper quadrants.

• In the subscapular and axillary lymph nodes from the outer quadrants.

In this situation, the detection of the number of lymph nodes involved in the pathological process is of great importance – for the correct choice of therapeutic measures for malignant neoplasms of the breast.

There are 3 degrees of involvement of lymph nodes in the pathological process:

• Minimal changes in the nodes (small number of tumor cells).

• Significant changes in the nodes (tumor cells are easily palpable).

• Extracapsular lesions of the nodes (they are affected by a neoplasm that extends beyond the borders of the node).

Most often, the more lymph nodes are involved in the pathological process, the more pronounced the growth of the malignant neoplasm.

There is also a division of involvement in the pathological process of lymph nodes according to their number:

• There is no involvement of lymph nodes.

• 1-3 nodes involved.

• 4-9 nodes involved.

• 10 or more nodes involved.

Biopsy with further histological examination is the only reliable method that allows to detect the presence of tumor cells in the lymph nodes.

Please note that both health and your life depend on the timely examination and detection of involvement in the pathological process of the lymph nodes in malignant neoplasms of the breast.

Author of the article: Stepanyan Arus Araratovna

Breast oncologist, plastic surgeon, first qualification category

Publication date: 08.05.