The medulla of the thymus contains concentric rings of epithelial cells known as Hassall’s corpuscles.

The Thymus Gland: Development, Structure, and Function

The thymus gland is an encapsulated organ that develops from the third and fourth pharyngeal pouches. It descends to the anterior superior mediastinum and is subdivided into lobules, each consisting of a cortex and a medulla. The cortex is made up of tightly packed lymphocytes, while the medulla is mostly composed of epithelial cells. Hassall’s corpuscles, which are concentrically arranged medullary epithelial cells that may surround a keratinized center, are also present.

The inferior parathyroid glands, which also develop from the third pharyngeal pouch, may be located with the thymus gland. The thymus gland’s arterial supply comes from the internal mammary artery or pericardiophrenic arteries, while its venous drainage is to the left brachiocephalic vein. The thymus gland plays a crucial role in the development and maturation of T-cells, which are essential for the immune system’s proper functioning.

The primary function of the spleen is the removal of old or damaged red blood cells from circulation, which helps to maintain the health of the red cell mass. The other functions of the spleen are also important, but this is the main function.

The Anatomy and Function of the Spleen

The spleen is an organ located in the left upper quadrant of the abdomen. Its size can vary depending on the amount of blood it contains, but the typical adult spleen is 12.5cm long and 7.5cm wide, with a weight of 150g. The spleen is almost entirely covered by peritoneum and is separated from the 9th, 10th, and 11th ribs by both diaphragm and pleural cavity. Its shape is influenced by the state of the colon and stomach, with gastric distension causing it to resemble an orange segment and colonic distension causing it to become more tetrahedral.

The spleen has two folds of peritoneum that connect it to the posterior abdominal wall and stomach: the lienorenal ligament and gastrosplenic ligament. The lienorenal ligament contains the splenic vessels, while the short gastric and left gastroepiploic branches of the splenic artery pass through the layers of the gastrosplenic ligament. The spleen is in contact with the phrenicocolic ligament laterally.

The spleen has two main functions: filtration and immunity. It filters abnormal blood cells and foreign bodies such as bacteria, and produces properdin and tuftsin, which help target fungi and bacteria for phagocytosis. The spleen also stores 40% of platelets, reutilizes iron, and stores monocytes. Disorders of the spleen include massive splenomegaly, myelofibrosis, chronic myeloid leukemia, visceral leishmaniasis, malaria, Gaucher’s syndrome, portal hypertension, lymphoproliferative disease, haemolytic anaemia, infection, infective endocarditis, sickle-cell, thalassaemia, and rheumatoid arthritis.

JAK2 Mutation and Primary Polycythaemia

Polycythaemia is a condition characterized by an increase in the number of red blood cells in the body. In primary polycythaemia, over 95% of cases are associated with a mutation in the JAK2 pathway. This mutation causes the pathway to be constantly active, leading to the production of red blood cells even in the absence of erythropoietin (EPO). The most common mutation occurs in exon 12, affecting position V617F.

On the other hand, secondary causes of polycythaemia include COPD and smoking, which lower blood oxygenation and trigger the secretion of EPO by the kidney’s peritubular cells. ADPKD also promotes the secretion of increased EPO, resulting in the production and release of more red blood cells. Dehydration, on the other hand, reduces plasma volume, leading to an apparent/relative polycythaemia. While these factors can cause an increase in red blood cells, they are not associated with a primary haematological disorder like the JAK2 mutation.

Haematopoiesis: The Generation of Immune Cells

Haematopoiesis is the process by which immune cells are produced from haematopoietic stem cells in the bone marrow. These stem cells give rise to two main types of progenitor cells: myeloid and lymphoid progenitor cells. All immune cells are derived from these progenitor cells.

The myeloid progenitor cells generate cells such as macrophages/monocytes, dendritic cells, neutrophils, eosinophils, basophils, and mast cells. On the other hand, lymphoid progenitor cells give rise to T cells, NK cells, B cells, and dendritic cells.

This process is essential for the proper functioning of the immune system. Without haematopoiesis, the body would not be able to produce the necessary immune cells to fight off infections and diseases. Understanding haematopoiesis is crucial in developing treatments for diseases that affect the immune system.

Invasion is a characteristic of invasive disease and is not typically seen in cases of DCIS. However, angiogenesis may be present in cases of high grade DCIS.

Characteristics of Malignancy in Histopathology

Histopathology is the study of tissue architecture and cellular changes in disease. In malignancy, there are several distinct characteristics that differentiate it from normal tissue or benign tumors. These features include abnormal tissue architecture, coarse chromatin, invasion of the basement membrane, abnormal mitoses, angiogenesis, de-differentiation, areas of necrosis, and nuclear pleomorphism.

Abnormal tissue architecture refers to the disorganized and irregular arrangement of cells within the tissue. Coarse chromatin refers to the appearance of the genetic material within the nucleus, which appears clumped and irregular. Invasion of the basement membrane is a hallmark of invasive malignancy, as it indicates that the cancer cells have broken through the protective layer that separates the tissue from surrounding structures. Abnormal mitoses refer to the process of cell division, which is often disrupted in cancer cells. Angiogenesis is the process by which new blood vessels are formed, which is necessary for the growth and spread of cancer cells. De-differentiation refers to the loss of specialized functions and characteristics of cells, which is common in cancer cells. Areas of necrosis refer to the death of tissue due to lack of blood supply or other factors. Finally, nuclear pleomorphism refers to the variability in size and shape of the nuclei within cancer cells.

Overall, these characteristics are important for the diagnosis and treatment of malignancy, as they help to distinguish cancer cells from normal tissue and benign tumors. By identifying these features in histopathology samples, doctors can make more accurate diagnoses and develop more effective treatment plans for patients with cancer.

The internal iliac lymph nodes are responsible for draining the lower part of the rectum, as well as the pelvic viscera and the anal canal above the pectinate line. The ileocolic nodes primarily drain the ileum and proximal ascending colon, while the inferior mesenteric nodes drain the hindgut structures from the transverse colon down to the superior portion of the rectum. The para-aortic nodes do not directly drain the lower part of the rectum, but they do receive drainage from the testes and ovaries.

Lymphatic drainage is the process by which lymphatic vessels carry lymph, a clear fluid containing white blood cells, away from tissues and organs and towards lymph nodes. The lymphatic vessels that drain the skin and follow venous drainage are called superficial lymphatic vessels, while those that drain internal organs and structures follow the arteries and are called deep lymphatic vessels. These vessels eventually lead to lymph nodes, which filter and remove harmful substances from the lymph before it is returned to the bloodstream.

The lymphatic system is divided into two main ducts: the right lymphatic duct and the thoracic duct. The right lymphatic duct drains the right side of the head and right arm, while the thoracic duct drains everything else. Both ducts eventually drain into the venous system.

Different areas of the body have specific primary lymph node drainage sites. For example, the superficial inguinal lymph nodes drain the anal canal below the pectinate line, perineum, skin of the thigh, penis, scrotum, and vagina. The deep inguinal lymph nodes drain the glans penis, while the para-aortic lymph nodes drain the testes, ovaries, kidney, and adrenal gland. The axillary lymph nodes drain the lateral breast and upper limb, while the internal iliac lymph nodes drain the anal canal above the pectinate line, lower part of the rectum, and pelvic structures including the cervix and inferior part of the uterus. The superior mesenteric lymph nodes drain the duodenum and jejunum, while the inferior mesenteric lymph nodes drain the descending colon, sigmoid colon, and upper part of the rectum. Finally, the coeliac lymph nodes drain the stomach.

Bone metastases can result in pathological fractures, which may be indicative of underlying conditions such as metastatic lung cancer. The appearance of certain lung cancers on X-ray can aid in the diagnosis of this condition. Other conditions such as granulomatosis with polyangiitis, adenocarcinoma of the lung, lung abscess, and multiple myeloma may also present with lung lesions, but do not fully explain the occurrence of a pathological fracture.

Bone Metastases: Common Tumours and Sites

Bone metastases occur when cancer cells from a primary tumour spread to the bones. The most common tumours that cause bone metastases are prostate, breast, and lung cancer, with prostate cancer being the most frequent. The most common sites for bone metastases are the spine, pelvis, ribs, skull, and long bones.

Aside from bone pain, other features of bone metastases may include pathological fractures, hypercalcaemia, and raised levels of alkaline phosphatase (ALP). Pathological fractures occur when the bone weakens due to the cancer cells, causing it to break. Hypercalcaemia is a condition where there is too much calcium in the blood, which can lead to symptoms such as fatigue, nausea, and confusion. ALP is an enzyme that is produced by bone cells, and its levels can be elevated in the presence of bone metastases.

A common diagnostic tool for bone metastases is an isotope bone scan, which uses technetium-99m labelled diphosphonates that accumulate in the bones. The scan can show multiple irregular foci of high-grade activity in the bones, indicating the presence of metastatic cancer. In the image provided, the bone scan shows multiple osteoblastic metastases in a patient with metastatic prostate cancer.

Filgrastim is a medication that stimulates the growth of granulocytes and is commonly used to treat neutropenia. In the case of a patient with a history of fever, low blood pressure, and tachycardia, it is likely that they have developed sepsis, which is a common complication in patients receiving chemotherapy. The main treatment for sepsis is fluid resuscitation and broad-spectrum antibiotics. While filgrastim is not a direct treatment for sepsis, it can be used to address leukopenia caused by chemotherapy, aplastic anemia, and congenital neutropenia.

Darbepoetin is a medication that mimics the effects of erythropoietin and is commonly used to treat anemia, particularly in patients with renal failure.

Eltrombopag is a medication that activates the TPO receptor and is often used to treat autoimmune thrombocytopenia.

IFN-γ is a medication used to treat chronic granulomatous disease.

Granulocyte-Colony Stimulating Factors for Neutropenia

Granulocyte-colony stimulating factors (G-CSFs) are synthetic versions of a natural protein that stimulates the production of white blood cells called neutrophils. These drugs are used to increase neutrophil counts in patients who are neutropenic, meaning they have abnormally low levels of neutrophils. Neutropenia can occur as a side effect of chemotherapy or radiation therapy, or due to other factors such as infections or autoimmune disorders.

Recombinant human G-CSFs, such as filgrastim and perfilgrastim, are commonly used to treat neutropenia. These drugs work by stimulating the bone marrow to produce more neutrophils, which can help prevent infections and other complications associated with low white blood cell counts. G-CSFs are typically administered by injection, either subcutaneously or intravenously.

Overall, G-CSFs are an important tool in the management of neutropenia, particularly in patients undergoing chemotherapy or other treatments that can suppress the immune system. By boosting neutrophil production, these drugs can help reduce the risk of infections and improve outcomes for patients with compromised immune function.

The sigmoid colon’s lymphatic drainage flows into the inferior mesenteric nodes. This is due to the embryological development of the vasculature supply in the hindgut region, which includes the transverse colon down to the rectum. From there, lymph eventually passes to the para-aortic nodes. The axillary nodes are not involved in this process, as they drain the upper limb and lateral breast tissue. Similarly, the internal iliac nodes drain different areas, including the inferior rectum, anal canal above the pectinate line, and pelvic viscera.

Lymphatic drainage is the process by which lymphatic vessels carry lymph, a clear fluid containing white blood cells, away from tissues and organs and towards lymph nodes. The lymphatic vessels that drain the skin and follow venous drainage are called superficial lymphatic vessels, while those that drain internal organs and structures follow the arteries and are called deep lymphatic vessels. These vessels eventually lead to lymph nodes, which filter and remove harmful substances from the lymph before it is returned to the bloodstream.

The lymphatic system is divided into two main ducts: the right lymphatic duct and the thoracic duct. The right lymphatic duct drains the right side of the head and right arm, while the thoracic duct drains everything else. Both ducts eventually drain into the venous system.

Different areas of the body have specific primary lymph node drainage sites. For example, the superficial inguinal lymph nodes drain the anal canal below the pectinate line, perineum, skin of the thigh, penis, scrotum, and vagina. The deep inguinal lymph nodes drain the glans penis, while the para-aortic lymph nodes drain the testes, ovaries, kidney, and adrenal gland. The axillary lymph nodes drain the lateral breast and upper limb, while the internal iliac lymph nodes drain the anal canal above the pectinate line, lower part of the rectum, and pelvic structures including the cervix and inferior part of the uterus. The superior mesenteric lymph nodes drain the duodenum and jejunum, while the inferior mesenteric lymph nodes drain the descending colon, sigmoid colon, and upper part of the rectum. Finally, the coeliac lymph nodes drain the stomach.

To divide the breast into four quadrants, one can visualize a vertical and horizontal line passing through the nipple. The superior lateral quadrant is where breast malignancies are most frequently detected. During a breast examination, it is crucial to palpate all quadrants and the axillary tail (which is part of the superior lateral quadrant). The quadrants also play a significant role in lymphatic drainage, as the medial quadrants can drain to the opposite side.

Breast Cancer Pathology: Understanding the Histological Features

Breast cancer pathology involves examining the histological features of the cancer cells to determine the underlying diagnosis. The invasive component of breast cancer is typically made up of ductal cells, although invasive lobular cancer may also occur. In situ lesions, such as DCIS, may also be present.

When examining breast cancer pathology, several typical changes are seen in conjunction with invasive breast cancer. These include nuclear pleomorphism, coarse chromatin, angiogenesis, invasion of the basement membrane, dystrophic calcification (which may be seen on mammography), abnormal mitoses, vascular invasion, and lymph node metastasis.

To grade the primary tumor, a scale of 1-3 is used, with 1 being the most benign lesion and 3 being the most poorly differentiated. Immunohistochemistry for estrogen receptor and herceptin status is routinely performed to further understand the cancer’s characteristics.

The grade, lymph node stage, and size are combined to provide the Nottingham prognostic index, which helps predict the patient’s prognosis and guide treatment decisions. Understanding the histological features of breast cancer is crucial in determining the best course of treatment for patients.

Genital warts are caused by HPV subtypes 6 and 11, which are non-carcinogenic. These warts are sexually transmitted and can also affect the larynx. While they do not pose a cancer risk, they can be psychologically distressing and require treatment such as podophyllotoxin ointment, cryotherapy, or surgical removal. Recurrence is possible due to HPV ability to remain dormant.

In contrast, HPV subtypes 16 and 18 are carcinogenic and linked to various cancers, but do not cause warts.

Syphilis, caused by Treponema pallidum, presents with a painless ulcer during the primary stage and can develop wart-like lesions during secondary syphilis, although this is rare compared to genital warts. Chlamydia trachomatis is another common sexually transmitted infection with various symptoms.

HPV Infection and Cervical Cancer

Human papillomavirus (HPV) infection is the primary risk factor for cervical cancer, with subtypes 16, 18, and 33 being the most carcinogenic. Other common subtypes, such as 6 and 11, are associated with genital warts but are not carcinogenic. When endocervical cells become infected with HPV, they may undergo changes that lead to the development of koilocytes. These cells have distinct characteristics, including an enlarged nucleus, irregular nuclear membrane contour, hyperchromasia (darker staining of the nucleus), and a perinuclear halo. These changes are important diagnostic markers for cervical cancer and can be detected through Pap smears or other screening methods. Early detection and treatment of HPV infection and cervical cancer can greatly improve outcomes and reduce the risk of complications.

Ulcerative colitis, a type of inflammatory bowel disease characterized by bloody diarrhea, can be treated with various medications such as sulfasalazine, infliximab, 6-mercaptopurine, and in severe cases, a colectomy. 6-mercaptopurine is a purine analogue that is activated by HGPRTase, leading to decreased purine synthesis and reduced DNA synthesis. It is commonly used to treat non-malignant conditions like systemic lupus erythematosus, rheumatoid arthritis, and inflammatory bowel disease. On the other hand, 5-fluorouracil is a pyrimidine analogue that acts as an antimetabolite, interfering with DNA synthesis, and is used to treat colorectal and pancreatic cancer. Methotrexate, an antimetabolite that acts as a folic acid analogue, is widely used in many malignancies and non-malignant conditions such as rheumatoid arthritis, psoriasis, and inflammatory bowel disease. Bleomycin, doxorubicin, and daunorubicin cause free radical formation, leading to breaks in the DNA strand, while busulfan is an alkylating agent that causes cross-links in the DNA and is typically used to ablate a patient’s bone marrow before a bone marrow transplant.

Cytotoxic agents are drugs that are used to kill cancer cells. There are several types of cytotoxic agents, each with their own mechanism of action and potential adverse effects. Alkylating agents, such as cyclophosphamide, work by causing cross-linking in DNA. However, they can also cause haemorrhagic cystitis, myelosuppression, and transitional cell carcinoma. Cytotoxic antibiotics, like bleomycin and anthracyclines, degrade preformed DNA and stabilize DNA-topoisomerase II complex, respectively. However, they can also cause lung fibrosis and cardiomyopathy. Antimetabolites, such as methotrexate and fluorouracil, inhibit dihydrofolate reductase and thymidylate synthesis, respectively. However, they can also cause myelosuppression, mucositis, and liver or lung fibrosis. Drugs that act on microtubules, like vincristine and docetaxel, inhibit the formation of microtubules and prevent microtubule depolymerisation & disassembly, respectively. However, they can also cause peripheral neuropathy, myelosuppression, and paralytic ileus. Topoisomerase inhibitors, like irinotecan, inhibit topoisomerase I, which prevents relaxation of supercoiled DNA. However, they can also cause myelosuppression. Other cytotoxic drugs, such as cisplatin and hydroxyurea, cause cross-linking in DNA and inhibit ribonucleotide reductase, respectively. However, they can also cause ototoxicity, peripheral neuropathy, hypomagnesaemia, and myelosuppression.

The likely cause of the patient’s megaloblastic macrocytic anaemia is Methotrexate therapy, which can result in folate deficiency. This drug is commonly used in the treatment of rheumatoid arthritis. Lead poisoning, high alcohol intake, and hyperthyroidism are not likely causes of this type of anaemia. Pernicious anaemia, an autoimmune condition that can lead to B12 deficiency, is also not the cause in this case as the patient has normal B12 levels.

Understanding Macrocytic Anaemia

Macrocytic anaemia is a type of anaemia that can be classified into two categories: megaloblastic and normoblastic. Megaloblastic anaemia is caused by a deficiency in vitamin B12 or folate, which leads to the production of abnormally large red blood cells in the bone marrow. This type of anaemia can also be caused by certain medications, alcohol, liver disease, hypothyroidism, pregnancy, and myelodysplasia.

On the other hand, normoblastic anaemia is caused by an increase in the number of immature red blood cells, known as reticulocytes, in the bone marrow. This can occur as a result of certain medications, such as methotrexate, or in response to other underlying medical conditions.

It is important to identify the underlying cause of macrocytic anaemia in order to provide appropriate treatment. This may involve addressing any nutritional deficiencies, managing underlying medical conditions, or adjusting medications. With proper management, most cases of macrocytic anaemia can be successfully treated.

Salmonella and Staphylococcus aureus as Causes of Osteomyelitis

Salmonella species are responsible for more than half of osteomyelitis cases in patients with sickle cell disease. The higher incidence of salmonella infections is due to various factors. The gut wall’s micro-infarcts allow the bacteria to enter the bloodstream, causing infection. Additionally, impaired splenic function leads to a weakened immune response against the pathogen.

On the other hand, Staphylococcus aureus is the most common organism that causes osteomyelitis in the general population. Although other organisms can also cause osteomyelitis, they are less frequently implicated.

Dendritic cells are derived from both myeloid and lymphoid lineages.

Haematopoiesis: The Generation of Immune Cells

Haematopoiesis is the process by which immune cells are produced from haematopoietic stem cells in the bone marrow. These stem cells give rise to two main types of progenitor cells: myeloid and lymphoid progenitor cells. All immune cells are derived from these progenitor cells.

The myeloid progenitor cells generate cells such as macrophages/monocytes, dendritic cells, neutrophils, eosinophils, basophils, and mast cells. On the other hand, lymphoid progenitor cells give rise to T cells, NK cells, B cells, and dendritic cells.

This process is essential for the proper functioning of the immune system. Without haematopoiesis, the body would not be able to produce the necessary immune cells to fight off infections and diseases. Understanding haematopoiesis is crucial in developing treatments for diseases that affect the immune system.

The presence of factor V Leiden mutation leads to resistance to activated protein C.

The most probable cause of the patient’s recurrent DVTs and family history of thrombo-embolic events is factor V Leiden, which is the most common inherited thrombophilia. This mutation results in activated protein C resistance, as activated factor V is not inactivated as efficiently by protein C.

Antiphospholipid syndrome is an acquired thrombophilia that can cause both arterial and venous thromboses, and may present with thrombocytopenia. However, the patient’s positive family history and normal full blood count make this diagnosis less likely than factor V Leiden.

Protein C deficiency, protein S deficiency, and antithrombin III deficiency are all inherited thrombophilias, but they are less prevalent in the population compared to factor V Leiden. Therefore, they are less likely to be the underlying cause of the patient’s symptoms.

Understanding Factor V Leiden

Factor V Leiden is a common inherited thrombophilia, affecting around 5% of the UK population. It is caused by a mutation in the Factor V Leiden protein, resulting in activated factor V being inactivated 10 times more slowly by activated protein C than normal. This leads to activated protein C resistance, which increases the risk of venous thrombosis. Heterozygotes have a 4-5 fold risk of venous thrombosis, while homozygotes have a 10 fold risk, although the prevalence of homozygotes is much lower at 0.05%.

Despite its prevalence, screening for Factor V Leiden is not recommended, even after a venous thromboembolism. This is because a previous thromboembolism itself is a risk factor for further events, and specific management should be based on this rather than the particular thrombophilia identified.

Other inherited thrombophilias include Prothrombin gene mutation, Protein C deficiency, Protein S deficiency, and Antithrombin III deficiency. The table below shows the prevalence and relative risk of venous thromboembolism for each of these conditions.

Overall, understanding Factor V Leiden and other inherited thrombophilias can help healthcare professionals identify individuals at higher risk of venous thrombosis and provide appropriate management to prevent future events.

Condition | Prevalence | Relative risk of VTE
— | — | —
Factor V Leiden (heterozygous) | 5% | 4
Factor V Leiden (homozygous) | 0.05% | 10
Prothrombin gene mutation (heterozygous) | 1.5% | 3
Protein C deficiency | 0.3% | 10
Protein S deficiency | 0.1% | 5-10
Antithrombin III deficiency | 0.02% | 10-20

The thoracoacromial artery originates from the axillary artery’s second part. It is a broad, brief trunk that penetrates the clavipectoral fascia and terminates by dividing into four branches, located deep to pectoralis major.

The Thoracoacromial Artery and its Branches

The thoracoacromial artery is a short trunk that originates from the axillary artery and is usually covered by the upper edge of the Pectoralis minor. It projects forward to the upper border of the Pectoralis minor and pierces the coracoclavicular fascia, dividing into four branches: pectoral, acromial, clavicular, and deltoid.

The pectoral branch descends between the two Pectoral muscles and supplies them and the breast, anastomosing with the intercostal branches of the internal thoracic artery and the lateral thoracic artery. The acromial branch runs laterally over the coracoid process and under the Deltoid, giving branches to it before piercing the muscle and ending on the acromion in an arterial network formed by branches from the suprascapular, thoracoacromial, and posterior humeral circumflex arteries. The clavicular branch runs upwards and medially to the sternoclavicular joint, supplying this articulation and the Subclavius. The deltoid branch arises with the acromial branch, crosses over the Pectoralis minor, and passes in the same groove as the cephalic vein, giving branches to both the Pectoralis major and Deltoid muscles.

Cyclophosphamide is a medication that is used to treat various types of cancer and induce immunosuppression in patients before stem cell transplantation. It works by causing cross-linking in DNA. However, one of the complications of cyclophosphamide treatment is haemorrhagic cystitis. This occurs because when the liver breaks down cyclophosphamide, it releases a toxic metabolite called acrolein. Acrolein is concentrated in the bladder and triggers an inflammatory response that can lead to haemorrhagic cystitis.

To reduce the risk of haemorrhagic cystitis, doctors can administer MESNA, a drug that conjugates acrolein and reduces the inflammatory response.

Bleomycin, on the other hand, degrades preformed DNA instead of causing cross-linking. Hydroxyurea inhibits ribonucleotide reductase, which decreases DNA synthesis. 5-Fluorouracil (5-FU) is a pyrimidine analogue that arrests the cell cycle and induces apoptosis. Vincristine inhibits the formation of microtubules.

Cytotoxic agents are drugs that are used to kill cancer cells. There are several types of cytotoxic agents, each with their own mechanism of action and potential adverse effects. Alkylating agents, such as cyclophosphamide, work by causing cross-linking in DNA. However, they can also cause haemorrhagic cystitis, myelosuppression, and transitional cell carcinoma. Cytotoxic antibiotics, like bleomycin and anthracyclines, degrade preformed DNA and stabilize DNA-topoisomerase II complex, respectively. However, they can also cause lung fibrosis and cardiomyopathy. Antimetabolites, such as methotrexate and fluorouracil, inhibit dihydrofolate reductase and thymidylate synthesis, respectively. However, they can also cause myelosuppression, mucositis, and liver or lung fibrosis. Drugs that act on microtubules, like vincristine and docetaxel, inhibit the formation of microtubules and prevent microtubule depolymerisation & disassembly, respectively. However, they can also cause peripheral neuropathy, myelosuppression, and paralytic ileus. Topoisomerase inhibitors, like irinotecan, inhibit topoisomerase I, which prevents relaxation of supercoiled DNA. However, they can also cause myelosuppression. Other cytotoxic drugs, such as cisplatin and hydroxyurea, cause cross-linking in DNA and inhibit ribonucleotide reductase, respectively. However, they can also cause ototoxicity, peripheral neuropathy, hypomagnesaemia, and myelosuppression.

Haptoglobins are responsible for binding free haemoglobin within the circulation, allowing for the complex to be removed from the circulation by the reticuloendothelial system. Therefore, the correct answer is 2 – haptoglobins. LDH, albumin, and bilirubin do not play a role in recycling free haemoglobin.

Understanding Haemolytic Anaemias by Site

Haemolytic anaemias can be classified by the site of haemolysis, either intravascular or extravascular. In intravascular haemolysis, free haemoglobin is released and binds to haptoglobin. As haptoglobin becomes saturated, haemoglobin binds to albumin forming methaemalbumin, which can be detected by Schumm’s test. Free haemoglobin is then excreted in the urine as haemoglobinuria and haemosiderinuria. Causes of intravascular haemolysis include mismatched blood transfusion, red cell fragmentation due to heart valves, TTP, DIC, HUS, paroxysmal nocturnal haemoglobinuria, and cold autoimmune haemolytic anaemia.

On the other hand, extravascular haemolysis occurs when red blood cells are destroyed by macrophages in the spleen or liver. This type of haemolysis is commonly seen in haemoglobinopathies such as sickle cell anaemia and thalassaemia, hereditary spherocytosis, haemolytic disease of the newborn, and warm autoimmune haemolytic anaemia.

It is important to understand the site of haemolysis in order to properly diagnose and treat haemolytic anaemias. While both intravascular and extravascular haemolysis can lead to anaemia, the underlying causes and treatment approaches may differ.

Bernard-Soulier syndrome is a bleeding disorder that occurs due to an autosomal recessive deficiency in the platelet glycoprotein complex Ib-IX-V. This complex is responsible for binding to von Willebrand factor (vWF) to allow platelet adherence. As a result of the deficiency, vWF cannot bind, leading to impaired platelet adhesion and the typical symptoms of coagulopathies such as abnormal bleeding and bruising.

It is important to note that von Willebrand factor is not deficient in Bernard-Soulier syndrome, but its function is impaired due to the lack of the platelet glycoprotein complex Ib-IX-V, which prevents it from binding to platelets.

Glanzmann’s disease is caused by a deficiency or dysfunction of platelet glycoprotein IIb/IIIa, which leads to impaired platelet aggregation as fibrinogen cannot bind to platelets.

Grey platelet syndrome, on the other hand, is characterized by alpha granule deficiency, where megakaryocytes fail to pack these granules into platelets and release them in the bone marrow. This results in a large number of agranulocytic platelets in blood smears, which is a diagnostic characteristic of the syndrome.

Finally, lack of fibrinogen is usually an acquired type of deficiency that may or may not present with clinical manifestations.

Understanding Bernard-Soulier Disease

Bernard-Soulier disease is a platelet disorder that is caused by a deficiency of the glycoprotein Ib/IX/V complex. This complex is responsible for acting as a receptor for von Willebrand factor. The disease is rare and inherited in an autosomal recessive manner. This means that an individual must inherit two copies of the mutated gene, one from each parent, to develop the disease. The lack of the glycoprotein Ib/IX/V complex leads to abnormal platelet function, which can result in bleeding tendencies and easy bruising. It is important for individuals with Bernard-Soulier disease to receive proper medical care and management to prevent complications.