肝臓（かんぞう、希: ἧπαρ (hepar)、羅: iecur、独: Leber、英: Liver）は、ヒトの場合は腹部の右上に位置する内臓である。ヒトにおいては最大の内臓であり^[1]、機能も多く、特に生体の内部環境の維持に大きな役割を果たしている。

概説

肝臓は、腹部の右上に位置して、ほぼ右肋骨の下に収まっており^[2]、頭側（上方）には横隔膜が存在する。ある種の動物では体内で最大の臓器である。非常に機能が多いことで知られ、代謝、排出、胎児の造血、解毒、体液の恒常性の維持などの役割を担っている。また、十二指腸に胆汁を分泌して消化にも一定の役割を持っている。

働きは判明しているだけで500種類以上あるとされ、肝機能を人工装置によって全面的に補うことは難しい^[3]。そのため、肝細胞と人工装置との組み合わせによるハイブリッド型の人工肝臓が主流となっている^[3]。

他方、臓器の中での部位による機能の分化が少なく再生能力が強いため、一部に損傷があっても症状に現れにくい^[1]。自覚症状の少なさから、「沈黙の臓器」などと呼ばれることがある^[1]。

牛・豚・鶏などの肝臓はレバーと呼ばれ、食材とされる。世界三大珍味のひとつフォアグラはガチョウやアヒルなどに大量のエサを与え肥大させた肝臓である。また魚類（アンコウ等）・軟体動物（イカ等）の肝臓も食用にされる。なお、大量に含まれるプリン体の影響により、多量の摂取は痛風などの原因とされることがある^[4]。また、ビタミンAが大量に蓄積されているシロクマやイシナギの肝臓や、テトロドトキシンが蓄積されているフグの肝臓のように、食べると危険なものもある。この他、牛や豚の肝臓は消化酵素を加えて加水分解され、肝臓水解物として二日酔いや慢性肝疾患治療の医薬品原料となる。

無脊椎動物のいくつかの群にも同様な器官があり、一般には中腸腺といわれる。カニミソなどもこれにあたる。

解剖

正常ヒト成人の肝重量は体重の約1/50であり、1.0 - 1.5kgである^[1]。

肝臓は肝動脈と門脈の2つの血管により栄養を受け、血流は中心静脈、肝静脈を経て肝外へと流れる。肝動脈は、下行大動脈から分岐した腹腔動脈の枝である総肝動脈が固有肝動脈となり右肝動脈と左肝動脈へと分かれて肝内へ入る。

肝臓から出た総胆管はファーター膨大部の手前で膵管と合流して、十二指腸と繋がる。なお、総胆管の途中に胆嚢がある。

解剖学的区分

解剖学的にヒトの肝臓は右葉、左葉、方形葉、尾状葉の4つに分けることができる。これは外観から見た分類であり、臨床的にはあまり重要ではない。

なお、たとえ同じ哺乳類であっても、何葉に分かれているかは種によって違いが見られる。

機能的区分

手術や治療を行う際には門脈による区分が重要となる。機能的区分は門脈血流によって肝を区分したものである。肝臓を胆嚢と下大静脈を結ぶ主分割面（カントリー線、Cantlie's line）によって左葉と右葉に分割する。左葉はさらに肝鎌状間膜により内側区と外側区に分けられる。右葉はさらに右肝静脈により前区と後区に分けられる。

Couinaud（クイノー）の亜区域分類

肝をS1〜S8の8つの区域に分ける。

S1：尾状葉、S2：左葉外側後区域、S3：左葉外側前区域、S4：左葉内側区域、S5：右葉前下区域、S6：右葉後下区域、S7：右葉後上区域、S8：右葉前上区域

肝臓のCT解剖学

肝臓の部位診断においては区域解剖が非常に重要となる。これは部位によって手術法が異なるからである。肝臓外科の手術としては亜区域切除、区域切除、葉切除、拡大右葉切除が知られている。

肝門とは左葉内側区（S4）と尾状葉（S1）の間隙であり、門脈、固有肝動脈の入口、胆管の出口である。肝円索裂は肝円索（胎生期の臍静脈）の付く場であり外側区（S2,S3）と内側区（S4）を境界する。静脈索裂は胎生期の静脈管の走っていた間隙で尾状葉（S1）と外側区（S2,S3）を境界する。下大静脈溝と胆嚢窩を結ぶ線をカントリー線といい、外科的左葉と右葉を境界する。これらはCTにて常に確認できるわけではないが後述する脈管系が確認しにくい時に役に立つ。肝区域、肝亜区域を診断するには脈管系が一番わかりやすい。

肝臓の血管の基本構造は各亜区域の中央を門脈が各亜区域の境界を肝静脈が走行することである。門脈には肝動脈と胆管が並走し、この構造は肝小葉レベルまで存続する。肝静脈は大きく左、中、右の3本を基本とする。左肝静脈本幹は左葉外側区（S2,S3）の中央を走り、外側後亜区（S2）と外側前亜区（S3）を境界する。中肝静脈本幹は内側区（S4）と右葉前区（S5,S8）を境界する。これはカントリー線にほぼ一致する境界となる。右肝静脈本幹は右葉の中央を貫き右葉前区（S5,S8）と後区（S6,S7）を境界する。

門脈本幹は左葉主枝と右葉主枝に分かれる。左葉枝は肝円索裂にはいり、まず外側後亜区域枝を分枝し、さらに腹側に延びて左右に外側前亜区域枝と内側区域枝に分かれる。この部分はかつて臍静脈が交通していたためU点という。右葉枝は前区域枝と後区域枝に分かれる。前区域枝は前上亜区域枝、前下亜区域枝に分かれる。後区域枝分枝部はP点といわれる。後区域枝は後上亜区域枝と後下亜区域枝に分かれる。門脈は支配する区域に合わせてPxと表現することもある。たとえば、前上亜区域（S7）の中央を走る門脈はP7である。

クイノー分類は肝亜区域の表現でよく用いられる、これは肝臓の内臓面からみて反時計回りに番号を振ったものである。内臓面から確認できない右葉前上亜区をS8としている。

組織

肝臓の組織は肝小葉と言う構造単位が集まってできており、小葉の間（小葉間結合組織）を小葉間静脈（肝門脈の枝）、小葉間動脈、小葉間胆管が走っている^[5]。肝小葉は直径1〜2mmの六角柱の形をしており、その中軸部は中心静脈という小静脈が貫いている^[5]。肝細胞は中心静脈の周囲に放射状に配列しており、ブロック塀の様に積み重なり、1層の板を形成している^[5]。その間を管腔の広い特殊な毛細血管が走っており、これを洞様毛細血管（あるいは類洞）という^[5]。この毛細血管は小葉間静脈と小葉間動脈の血液を受けて中心静脈に血液を送る。

一方、肝細胞板の内部で、隣り合う肝細胞間には毛細胆管というごく細い管が作られている^[6]。肝細胞から分泌された胆汁はこの毛細胆管に分泌され、小葉中心部から小葉間胆管に注いでいる。 また、人間の場合肝臓の細胞は核を2つ持つ多核細胞の1種であり、このことが肝細胞の再生力が高い要因とされている。

肝臓再生には肝細胞の肥大が重要な働きをしていることがわかっている^[7]。

機能

• 食物の消化を助ける胆汁酸を生成し、胆管・胆嚢から十二指腸に胆汁として分泌する^[8]。
• ヘムの分解物である間接ビリルビンをグルクロン酸抱合により直接ビリルビンにして胆汁として分泌する。
• 糖の代謝。

  血液中のグルコース濃度に応じて、血液中のグルコースをグリコーゲンとして貯蔵したり、貯蔵したグリコーゲンをグルコースに変換し、血液中へ放出したりする^[9]ことで、グルコース濃度を一定に保つことができる^[10]。

• 脂質の代謝。

  脂質を分解しエネルギーを作り出すことができる^[9]。胆汁酸はコレステロールの代謝産物である^[11]。

• コレステロール（ステロイドホルモンである性ホルモンや副腎皮質ホルモンの原料）の生合成。コレステロールの大部分は肝臓で合成されている。
• アミノ酸の代謝。

  アミノ酸からアルブミンやフィブリノゲンなどの血漿タンパク質を合成。

• アンモニアを尿素へ変換する^[9](オルニチン回路)。
• 薬物代謝およびアルコール代謝^[9]。
• ケトン体の合成（飢餓時などグルコース枯渇時の代替エネルギー源）。
• 筋肉などから血流にのって運ばれてきた乳酸からのグルコースの再合成（コリ回路）。
• 造血機能

  骨髄での造血が開始されるまでの間、肝臓と脾臓で造血されている。ヒトの場合、出生後は肝臓で造血されることはないが、何らかの理由で骨髄での造血が障害されると、肝臓での造血が見られることがある（髄外造血）。

• コレカルシフェロール（ビタミンD₃）を活性型のビタミンD₃であるカルシフェジオールに代謝。
• アンジオテンシノゲンの産生。
• エストロゲン（女性ホルモン）のコントロール。男性の場合、女性ホルモンを取り除く。

疾患

肝臓の疾患には以下のものが挙げられる。

• 脂肪肝
  • 非アルコール性脂肪性肝炎=NASH
• 肝硬変
  • 原発性胆汁性胆管炎=primary biliary cirrhosis=PBC
• 肝炎
  • ウイルス性肝炎
  • アルコール性肝炎
  • 自己免疫性肝炎=autoimmune hepatitis
• 肝癌
  • 肝細胞癌
  • 胆管細胞癌
  • 転移性肝癌 - 肝臓から始まる疾患ではないが、最終的に肝不全に至り、致死的となりうる。
• ヘモクロマトーシス - 鉄過剰症が原因。
• 原発性硬化性胆管炎=primary sclerosing cholangitis=PSC
• 肝レンズ核変性症
• 感染症
  • エキノコックス症
  • 肝膿瘍
  • 日本住血吸虫症

など

脂肪肝や肝炎ではアラニントランスアミナーゼ（ALT,またはGPT）、アスパラギン酸アミノ基転移酵素（AST,またはGOT）の血中濃度の上昇がみられ^[12]、これらの血中濃度の測定が診断に用いられる^[13]。いずれにしても肝機能が低下すると、生体が必要とする物質の合成が上手くできなくなったり、生体内で生成する老廃物、体外から摂取された有害物質や薬物の分解（代謝）が遅くなったり、肝臓での代謝を受けることで活性型になるプロドラッグが利用しにくくなったりと、様々な影響が出てくる。このため、特に重度の肝障害がある場合は、なるべく薬剤の使用を避けるようにする場合があったり、仮に投与するとしても減量が必要な場合があるなど、薬剤の使用には慎重さが求められる。なお、肝機能の著しい低下が起これば、それは致死的である。

肝移植

障害を受けた肝は再生する能力を持っているが、肝の障害が不可逆的であり自己再生が不可能になった場合には肝移植が行われることがある。なお、ヒトの他の臓器とは違って、肝臓は再生能力が強く、仮に一部を切り取ったとしても、まだ体内に充分なサイズの肝臓が残っていて、かつ、残された肝臓が健全であれば元の大きさにまで戻ることから、生体肝移植が行われることもある。ただし、いずれの場合も、仮にタクロリムスのような免疫抑制剤を受容患者に使うとしても、ある程度HLAの型が近いことが望ましいなど、肝移植に際しては様々な条件が存在する。

その他

• ギリシア神話では、人間に火を与えたプロメーテウスはゼウスの怒りを買い、カウカーソス山に磔にされ、毎日ハゲタカに肝臓をむさぼられるという罰を受けた。プロメーテウスも神であるため不死身であり、肝臓は翌日には再生してまた喰われる。
• かつての日本では梅毒、ハンセン病、結核などに対する薬効があるとする民間療法が存在しており、主に男性の刑死体の肝臓の塩干しが「脳味噌の黒焼き」や「人油」よりも高値で売られていた。山田浅右衛門の専売で「人丹」、「人胆丸」などと称されていた。丸薬で浅蜊貝より少し多い程度の貝殻一杯ほどが明治の初年に5円もした。1870年4月15日、販売禁止となった。里見弴の「ひえもんとり」は江戸時代の肝臓を奪い合う様子を描いている。
• ボクシング等の格闘技では、肝臓を狙って打つパンチを「レバーブロー」と呼ぶ。ボディブローの1種なのだが、鳩尾は腹直筋を鍛えることでダメージを軽減させやすいが、レバーブローは鍛えづらい脇腹を狙うため効果は大きい。肝臓に当たる部分に打撃を受けると、鈍い痛みと激しい苦痛を感じる。その為格闘家はメディシンボールや、体重を掛けたトレーニングパートナーの足の裏などで、自分の腹筋や内臓に激しい刺激を与えて鍛える。

数値

主な脊椎動物の肝臓重量比

数値は、肝臓重量比率はBuddenbrock 1956, Haltenorth 1977, Kolb 1974、胆汁生産量はBuddenbrock 1956から^[14]。

参考文献

• 『カラー図解 人体解剖の基本がわかる事典』 竹内修二、西東社、2012年3月5日、102頁。全国書誌番号:22048082。ISBN 978-4-7916-1834-7。
• 『機能形態学』 玄番宗一、化学同人〈ベーシック薬学教科書シリーズ〉、2008年3月10日、第1版。全国書誌番号:21475112。ISBN 978-4-7598-1264-0。
• 安達和俊 『現代社会の健康科学』 産学社、2008年3月10日。全国書誌番号:21547956。ISBN 978-4-7825-2068-0。
• 坂井建雄 『図解入門よくわかる解剖学の基本としくみ』 秀和システム〈図解入門メディカルサイエンス〉、2006年6月8日。全国書誌番号:21058390。ISBN 978-4-7980-1343-5。
• 『臨床栄養学 疾病編』 嶋津孝、下田妙子、化学同人〈エキスパート管理栄養士養成シリーズ〉、2010年3月31日、第2版。全国書誌番号:21760336。ISBN 978-4-7598-1229-9。

脚注

関連項目

• ビリルビン
• 脾臓
• 門脈

外部リンク

• 肝炎情報センター

The liver is a vital organ of vertebrates and some other animals.^[2] In the human, it is located in the upper right quadrant of the abdomen, below the diaphragm. The liver has a wide range of functions, including detoxification of various metabolites, protein synthesis, and the production of biochemicals necessary for digestion.^[3]

The liver is a gland and plays a major role in metabolism with numerous functions in the human body, including regulation of glycogen storage, decomposition of red blood cells, plasma protein synthesis, hormone production, and detoxification.^[3] It is an accessory digestive gland and produces bile, an alkaline compound which aids in digestion via the emulsification of lipids. The gallbladder, a small pouch that sits just under the liver, stores bile produced by the liver.^[4] The liver's highly specialized tissue consisting of mostly hepatocytes regulates a wide variety of high-volume biochemical reactions, including the synthesis and breakdown of small and complex molecules, many of which are necessary for normal vital functions.^[5] Estimates regarding the organ's total number of functions vary, but textbooks generally cite it being around 500.^[6]

Terminology related to the liver often starts in hepat- from ἡπατο-, the Greek word for liver.^[7]

There is currently no way to compensate for the absence of liver function in the long term, although liver dialysis techniques can be used in the short term. Artificial livers are yet to be developed to promote long term replacement in the absence of the liver. As of now,^[8] liver transplantation is the only option for complete liver failure.

Structure

The liver is a reddish-brown wedge-shaped organ with four lobes of unequal size and shape. A human liver normally weighs 1.44–1.66 kg (3.2–3.7 lb).^[9] It is both the heaviest internal organ and the largest gland in the human body. Located in the right upper quadrant of the abdominal cavity, it rests just below the diaphragm, to the right of the stomach and overlies the gallbladder.^[4]

The liver is connected to two large blood vessels: the hepatic artery and the portal vein. The hepatic artery carries oxygen-rich blood from the aorta, whereas the portal vein carries blood rich in digested nutrients from the entire gastrointestinal tract and also from the spleen and pancreas.^[8] These blood vessels subdivide into small capillaries known as liver sinusoids, which then lead to a lobule.

Lobules are the functional units of the liver. Each lobule is made up of millions of hepatic cells (hepatocytes) which are the basic metabolic cells. The lobules are held together by a fine dense irregular fibroelastic connective tissue layer which extends into the structure of the liver, by accompanying the vessels (veins and arteries) ducts and nerves through the hepatic portal, as a fibrous capsule called Glisson's capsule.^[10] The whole surface of the liver is covered in a serous coat derived from peritoneum and this has an inner fibrous coat (Glisson's capsule) to which it is firmly adhered. The fibrous coat is of areolar tissue and follows the vessels and ducts to support them.^[11]

Gross anatomy

Lobes

Gross anatomy traditionally divided the liver into two portions – a right and a left lobe, as viewed from the front (diaphragmatic) surface; but the underside (the visceral surface) shows it to be divided into four lobes and includes the caudate and quadrate lobes.^[12]

The falciform ligament, visible on the front of the liver, divides the liver into a left and a much larger right lobe. From the visceral surface, the two additional lobes are located between the right and left lobes, one in front of the other. A line can be imagined running from the left of the vena cava and all the way forward to divide the liver and gallbladder into two halves.^[13] This line is called Cantlie's line.^[14]

Other anatomical landmarks exist, such as the ligamentum venosum and the round ligament of the liver (ligamentum teres), which further divide the left side of the liver in two sections. An important anatomical landmark, the porta hepatis, also known as the transverse fissure of the liver, divides this left portion into four segments, which can be numbered starting at the caudate lobe as I in an anticlockwise manner. From this visceral view, seven segments can be seen, because the eighth segment is only visible in the parietal view.^[15]

Surfaces

On the diaphragmatic surface, apart from a small triangular bare area where it connects to the diaphragm, the liver is covered by a thin double-layered membrane, the peritoneum, that help reduces friction against other organs.^[16] This surface covers the convex shape of the two lobes where it accommodates the shape of the diaphragm. The peritoneum folds back on itself to form the falciform ligament and the right and left triangular ligaments.^[17]

These peritoneal ligaments are not related to the anatomic ligaments in joints, and the right and left triangular ligaments have no known functional importance, though they serve as surface landmarks.^[17] The falciform ligament functions to attach the liver to the posterior portion of the anterior body wall.

The visceral surface or inferior surface, is uneven and concave. It is covered in peritoneum apart from where it attaches the gallbladder and the porta hepatis.^[16]

Impressions

There are several impressions on the surface of the liver which accommodate the various adjacent structures and organs. Underneath the right lobe and to the right of the gallbladder fossa, are two impressions, one behind the other and separated by a ridge. The one in front is a shallow colic impression, formed by the hepatic flexure and the one behind is a deeper renal impression accommodating part of the right kidney and part of the suprarenal gland.^[18]

The suprarenal impression is a small triangular depressed area on the liver. It is located close to the right of the fossa between the bare area and the caudate lobe and immediately above the renal impression. The greater part of the suprarenal impression is devoid of peritoneum and it lodges the right suprarenal gland.^[19]

Medial to the renal impression is a third and slightly marked impression, lying between it and the neck of the gall-bladder. This is caused by the descending portion of the duodenum, and is known as the duodenal impression.^[19]

The inferior surface of the left lobe of the liver presents behind and to the left the gastric impression.^[19] This is moulded over the upper front surface of the stomach, and to the right of this is a rounded eminence, the tuber omentale, which fits into the concavity of the lesser curvature of the stomach and lies in front of the anterior layer of the lesser omentum.

Microscopic anatomy

Microscopically, each liver lobe is seen to be made up of hepatic lobules. The lobules are roughly hexagonal, and consist of plates of hepatocytes radiating from a central vein.^{[20][page needed]}The central vein joins to the hepatic vein to carry blood out from the liver. A distinctive component of a lobule is the portal triad, which can be found running along each of the lobule's corners. The portal triad, misleadingly named, consists of five structures: a branch of the hepatic artery, a branch of the hepatic portal vein, and a bile duct, as well as lymphatic vessels and a branch of the vagus nerve.^[21] Between the hepatocyte plates are liver sinusoids, which are enlarged capillaries through which blood from the hepatic portal vein and hepatic artery enters via the portal triads, then drains to the central vein.^{[20][page needed]}

Histology, the study of microscopic anatomy, shows two major types of liver cell: parenchymal cells and non-parenchymal cells. 70–85% of the liver volume is occupied by parenchymal hepatocytes. Non-parenchymal cells constitute 40% of the total number of liver cells but only 6.5% of its volume.^[22] The liver sinusoids are lined with two types of cell, sinusoidal endothelial cells, and phagocytic Kupffer cells.^[23] Hepatic stellate cells are non-parenchymal cells found in the perisinusoidal space, between a sinusoid and a hepatocyte.^[22] Additionally, intrahepatic lymphocytes are often present in the sinusoidal lumen.^[22]

Functional anatomy

The central area or hilum, known as the porta hepatis is where the common bile duct, hepatic portal vein, and the hepatic artery proper enter the liver. The duct, vein, and artery divide into left and right branches, and the areas of the liver supplied by these branches constitute the functional left and right lobes. The functional lobes are separated by the imaginary plane, Cantlie's line, joining the gallbladder fossa to the inferior vena cava. The plane separates the liver into the true right and left lobes. The middle hepatic vein also demarcates the true right and left lobes. The right lobe is further divided into an anterior and posterior segment by the right hepatic vein. The left lobe is divided into the medial and lateral segments by the left hepatic vein.

Couinaud classification system

The fissure for the round ligament of the liver (ligamentum teres) also separates the medial and lateral segments. The medial segment is also called the quadrate lobe. In the widely used Couinaud (or "French") system, the functional lobes are further divided into a total of eight subsegments based on a transverse plane through the bifurcation of the main portal vein.^[24] The caudate lobe is a separate structure which receives blood flow from both the right- and left-sided vascular branches.^[25][26] The Couinaud classification of liver anatomy divides the liver into eight functionally independent segments. Each segment has its own vascular inflow, outflow and biliary drainage. In the centre of each segment there is a branch of the portal vein, hepatic artery and bile duct. In the periphery of each segment there is vascular outflow through the hepatic veins.^[27] The division of the liver into independent units means that segments can be resected without damaging the remaining segments.^[28] To preserve the viability of the liver following surgery, resections follow the vessels defining the peripheries of each segment. This means that resection lines parallel the hepatic veins, leaving the portal veins, bile ducts, and hepatic arteries intact.^[24]

The classification system uses the vascular supply in the liver to separate the functional units (numbered I to VIII):

• Unit I is the caudate lobe and is situated posterior l and it may receive its supply from both the right and the left branches of portal vein. It contains one or more hepatic veins which drain directly into the IVC.^[24]

The remainder of the units (II to VIII) are numbered in a clockwise fashion:^[27]

• units II and III lie medial to the falciform ligament with II superior to the portal venous supply and III inferior
• unit IV lies lateral to the falciform ligament and is subdivided into IVa (superior) and IVb (inferior)

Units V to VIII make up the right part of the liver:^[27]

• unit V is the most medial and inferior
• unit VI is located more posteriorly
• unit VII is located above unit VI
• unit VIII sits above unit V in the superio-medial position

Development

Organogenesis, the development of the organs takes place from the third to the eighth week during embryogenesis. The origins of the liver lie in both the ventral portion of the foregut endoderm (endoderm being one of the 3 embryonic germ layers) and the constituents of the adjacent septum transversum mesenchyme. In the human embryo, the hepatic diverticulum is the tube of endoderm that extends out from the foregut into the surrounding mesenchyme. The mesenchyme of septum transversum induces this endoderm to proliferate, to branch, and to form the glandular epithelium of the liver. A portion of the hepatic diverticulum (that region closest to the digestive tube) continues to function as the drainage duct of the liver, and a branch from this duct produces the gallbladder.^[29] Besides signals from the septum transversum mesenchyme, fibroblast growth factor from the developing heart also contributes to hepatic competence, along with retinoic acid emanating from the lateral plate mesoderm. The hepatic endodermal cells undergo a morphological transition from columnar to pseudostratified resulting in thickening into the early liver bud. Their expansion forms a population of the bipotential hepatoblasts.^[30] Hepatic stellate cells are derived from mesenchyme.^[31]

After migration of hepatoblasts into the septum transversum mesenchyme, the hepatic architecture begins to be established, with liver sinusoids and bile canaliculi appearing. The liver bud separates into the lobes. The left umbilical vein becomes the ductus venosus and the right vitelline vein becomes the portal vein. The expanding liver bud is colonized by hematopoietic cells. The bipotential hepatoblasts begin differentiating into biliary epithelial cells and hepatocytes. The biliary epithelial cells differentiate from hepatoblasts around portal veins, first producing a monolayer, and then a bilayer of cuboidal cells. In ductal plate, focal dilations emerge at points in the bilayer, become surrounded by portal mesenchyme, and undergo tubulogenesis into intrahepatic bile ducts. Hepatoblasts not adjacent to portal veins instead differentiate into hepatocytes and arrange into cords lined by sinudoidal epithelial cells and bile canaliculi. Once hepatoblasts are specified into hepatocytes and undergo further expansion, they begin acquiring the functions of a mature hepatocyte, and eventually mature hepatocytes appear as highly polarized epithelial cells with abundant glycogen accumulation. In the adult liver, hepatocytes are not equivalent, with position along the portocentrovenular axis within a liver lobule dictating expression of metabolic genes involved in drug metabolism, carbohydrate metabolism, ammonia detoxification, and bile production and secretion. WNT/β-catenin has now been identified to be playing a key role in this phenomenon.^[30]

At birth the liver comprises roughly 4% of body weight and is at average 120 g. Over the course of further development, it will increase to 1.4–1.6 kg but will only take up 2.5–3.5% of body weight.^[32]

Fetal blood supply

In the growing fetus, a major source of blood to the liver is the umbilical vein which supplies nutrients to the growing fetus. The umbilical vein enters the abdomen at the umbilicus, and passes upward along the free margin of the falciform ligament of the liver to the inferior surface of the liver. There it joins with the left branch of the portal vein. The ductus venosus carries blood from the left portal vein to the left hepatic vein and then to the inferior vena cava, allowing placental blood to bypass the liver.

In the fetus, the liver does not perform the normal digestive processes and filtration of the infant liver because nutrients are received directly from the mother via the placenta. The fetal liver releases some blood stem cells that migrate to the fetal thymus, creating the T-cells or T-lymphocytes. After birth, the formation of blood stem cells shifts to the red bone marrow.

After two to five days, the umbilical vein and ductus venosus are completely obliterated; the former becomes the round ligament of liver and the latter becomes the ligamentum venosum. In the disorders of cirrhosis and portal hypertension, the umbilical vein can open up again.

Physiology

The various functions of the liver are carried out by the liver cells or hepatocytes. The liver is thought to be responsible for up to 500 separate functions, usually in combination with other systems and organs. Currently, there is no artificial organ or device capable of reproducing all the functions of the liver. Some functions can be carried out by liver dialysis, an experimental treatment for liver failure.

Blood supply

The liver receives a dual blood supply from the hepatic portal vein and hepatic arteries. The hepatic portal vein delivers approximately 75% of the liver's blood supply, and carries venous blood drained from the spleen, gastrointestinal tract, and its associated organs. The hepatic arteries supply arterial blood to the liver, accounting for the remaining quarter of its blood flow. Oxygen is provided from both sources; approximately half of the liver's oxygen demand is met by the hepatic portal vein, and half is met by the hepatic arteries.^[33]

Blood flows through the liver sinusoids and empties into the central vein of each lobule. The central veins coalesce into hepatic veins, which leave the liver and drain into the inferior vena cava.^[21]

Biliary flow

The biliary tract is derived from the branches of the bile ducts. The biliary tract, also known as the biliary tree, is the path by which bile is secreted by the liver then transported to the first part of the small intestine, the duodenum. The bile produced in the liver is collected in bile canaliculi, small grooves between the faces of adjacent hepatocytes. The canaliculi radiate to the edge of the liver lobule, where they merge to form bile ducts. Within the liver, these ducts are termed intrahepatic bile ducts, and once they exit the liver they are considered extrahepatic. The intrahepatic ducts eventually drain into the right and left hepatic ducts, which exit the liver at the transverse fissure, and merge to form the common hepatic duct. The cystic duct from the gallbladder joins with the common hepatic duct to form the common bile duct.^[21]

Bile either drains directly into the duodenum via the common bile duct, or is temporarily stored in the gallbladder via the cystic duct. The common bile duct and the pancreatic duct enter the second part of the duodenum together at the hepatopancreatic ampulla, also known as the ampulla of Vater.

Synthesis

The liver plays a major role in carbohydrate, protein, amino acid, and lipid metabolism.

The liver performs several roles in carbohydrate metabolism: The liver synthesizes and stores approximately 100g of glycogen via glycogenesis, the formation of glycogen from glucose. When needed, the liver releases glucose into the blood by performing glycogenolysis, the breakdown of glycogen into glucose.^[34] The liver is also responsible for gluconeogenesis, which is the synthesis of glucose from certain amino acids, lactate or glycerol. Adipose and liver cells produce glycerol by breakdown of fat, which the liver uses for gluconeogenesis.^[34]

The liver is responsible for the mainstay of protein metabolism, synthesis as well as degradation. It is also responsible for a large part of amino acid synthesis. The liver plays a role in the production of clotting factors as well as red blood cell production. Some of the proteins synthesized by the liver include coagulation factors I (fibrinogen), II (prothrombin), V, VII, VIII, IX, X, XI, XIII, as well as protein C, protein S and antithrombin. In the first trimester fetus, the liver is the main site of red blood cell production. By the 32nd week of gestation, the bone marrow has almost completely taken over that task. The liver is a major site of production for thrombopoietin, a glycoprotein hormone that regulates the production of platelets by the bone marrow.^[35]

The liver plays several roles in lipid metabolism: it performs cholesterol synthesis, lipogenesis, the production of triglycerides, and a bulk of the body's lipoproteins are synthesized in the liver.

The liver plays a key role in digestion, as it produces and excretes bile (a yellowish liquid) required for emulsifying fats and help the absorption of vitamin K from the diet. Some of the bile drains directly into the duodenum, and some is stored in the gallbladder.

The liver also produces insulin-like growth factor 1 (IGF-1), a polypeptide protein hormone that plays an important role in childhood growth and continues to have anabolic effects in adults.

Breakdown

The liver is responsible for the breakdown of insulin and other hormones. The liver breaks down bilirubin via glucuronidation, facilitating its excretion into bile. The liver is responsible for the breakdown and excretion of many waste products. It plays a key role in breaking down or modifying toxic substances (e.g., methylation) and most medicinal products in a process called drug metabolism. This sometimes results in toxication, when the metabolite is more toxic than its precursor. Preferably, the toxins are conjugated to avail excretion in bile or urine. The liver breaks down ammonia into urea as part of the urea cycle, and the urea is excreted in the urine.^[20]

Other functions

• The liver stores a multitude of substances, including glucose (in the form of glycogen), vitamin A (1–2 years' supply), vitamin D (1–4 months' supply)^{[citation needed]}, vitamin B12 (3–5 years' supply),^[36] vitamin K, iron, and copper.
• The liver is responsible for immunological effects—the mononuclear phagocyte system of the liver contains many immunologically active cells, acting as a 'sieve' for antigens carried to it via the portal system.
• The liver produces albumin, the most abundant protein in blood serum. It is essential in the maintenance of oncotic pressure, and acts as a transport for fatty acids and steroid hormones.
• The liver synthesizes angiotensinogen, a hormone that is responsible for raising the blood pressure when activated by renin, an enzyme that is released when the kidney senses low blood pressure.
• The liver produces the enzyme catalase in order to break down hydrogen peroxide, a very toxic substance due to it being a powerful oxidising agent, into water and oxygen.

Relation to medicine and pharmacology

The oxidative capacity of the liver decreases with aging and therefore any medications that require oxidation (for instance, benzodiazepines) are more likely to accumulate to toxic levels. However, medications with shorter half-lives, such as lorazepam and oxazepam, are preferred in most cases when benzodiazepines are required in regard to geriatric medicine.

Clinical significance

Disease

The liver is a vital organ and supports almost every other organ in the body. Because of its strategic location and multidimensional functions, the liver is also prone to many diseases.^[37] The bare area of the liver is a site that is vulnerable to the passing of infection from the abdominal cavity to the thoracic cavity.

Hepatitis is a common condition of inflammation of the liver. The most usual cause of this is viral, and the most common of these infections are hepatitis A, B, C, D, and E. Some of these infections are sexually transmitted. Inflammation can also be caused by other viruses in the Herpesviridae family such as the herpes simplex virus. Infection with hepatitis B virus or hepatitis C virus is the main cause of liver cancer.^[38]

Hepatic encephalopathy is caused by an accumulation of toxins in the bloodstream that are normally removed by the liver. This condition can result in coma and can prove fatal.

Other disorders caused by excessive alcohol consumption are grouped under alcoholic liver diseases and these include alcoholic hepatitis, fatty liver, and cirrhosis. Factors contributing to the development of alcoholic liver diseases are not only the quantity and frequency of alcohol consumption, but can also include gender, genetics, and liver insult.^[39]

Liver damage can also be caused by drugs, particularly paracetamol and drugs used to treat cancer.

Budd–Chiari syndrome is a condition caused by blockage of the hepatic veins (including thrombosis) that drain the liver. It presents with the classical triad of abdominal pain, ascites and liver enlargement.^[40]

Primary biliary cirrhosis is an autoimmune disease of the liver.^[41][42] It is marked by slow progressive destruction of the small bile ducts of the liver, with the intralobular ducts (Canals of Hering) affected early in the disease.^[43] When these ducts are damaged, bile and other toxins build up in the liver (cholestasis) and over time damages the liver tissue in combination with ongoing immune related damage. This can lead to scarring (fibrosis) and cirrhosis.

Many diseases of the liver are accompanied by jaundice caused by increased levels of bilirubin in the system. The bilirubin results from the breakup of the hemoglobin of dead red blood cells; normally, the liver removes bilirubin from the blood and excretes it through bile.

There are also many pediatric liver diseases, including biliary atresia, alpha-1 antitrypsin deficiency, alagille syndrome, progressive familial intrahepatic cholestasis, Langerhans cell histiocytosis and hepatic hemangioma a benign tumour the most common type of liver tumour, thought to be congenital. Diseases that interfere with liver function will lead to derangement of these processes. However, the liver has a great capacity to regenerate and has a large reserve capacity. In most cases, the liver only produces symptoms after extensive damage.

Hepatomegaly refers to an enlarged liver and can be due to many causes. It can be palpated in a liver span measurement.

Liver diseases may be diagnosed by liver function tests–blood tests that can identify various markers. For example, acute-phase reactants are produced by the liver in response to injury or inflammation.

Symptoms

The classic symptoms of liver damage include the following:

• Pale stools occur when stercobilin, a brown pigment, is absent from the stool. Stercobilin is derived from bilirubin metabolites produced in the liver.
• Dark urine occurs when bilirubin mixes with urine
• Jaundice (yellow skin and/or whites of the eyes) This is where bilirubin deposits in skin, causing an intense itch. Itching is the most common complaint by people who have liver failure. Often this itch cannot be relieved by drugs.
• Swelling of the abdomen, ankles and feet occurs because the liver fails to make albumin.
• Excessive fatigue occurs from a generalized loss of nutrients, minerals and vitamins.
• Bruising and easy bleeding are other features of liver disease. The liver makes substances which help prevent bleeding. When liver damage occurs, these substances are no longer present and severe bleeding can occur.^[44]
• Pain in the upper right quadrant can result from the stretching of Glisson's capsule in conditions of hepatitis and pre-eclampsia.

Diagnosis

The diagnosis of liver disease is made by liver function tests, groups of blood tests, that can readily show the extent of liver damage. If infection is suspected, then other serological tests will be carried out. Sometimes, an ultrasound or a CT scan is needed to produce an image of the liver.

Physical examination of the liver can only reveal its size and any tenderness, and some form of imaging will also be needed.^[45]

• Axial CT image showing anomalous hepatic veins coursing on the subcapsular anterior surface of the liver.^[46]

• Maximum intensity projection (MIP) CT image as viewed anteriorly showing the anomalous hepatic veins coursing on the anterior surface of the liver

• Lateral MIP view in the same patient

• A CT scan in which the liver and portal vein are shown.

Biopsy / scan

Damage to the liver is sometimes determined with a biopsy, particularly when the cause of liver damage is unknown. In the 21st century they have been largely replaced by high-resolution radiographic scans. The latter do not require ultrasound guidance, lab involvement, microscopic analysis, organ damage, pain, or patient sedation; and the results are available immediately on a computer screen.^{[citation needed]}

In a biopsy, a needle is inserted into the skin just below the rib cage and a tissue sample obtained. The tissue is sent to the laboratory, where it is analyzed under a microscope. Sometimes, a radiologist may assist the physician performing a liver biopsy by providing ultrasound guidance.^[47]

Liver regeneration

The liver is the only human internal organ capable of natural regeneration of lost tissue; as little as 25% of a liver can regenerate into a whole liver.^[48] This is, however, not true regeneration but rather compensatory growth in mammals.^[49] The lobes that are removed do not regrow and the growth of the liver is a restoration of function, not original form. This contrasts with true regeneration where both original function and form are restored. In some other species, such as fish, the liver undergoes true regeneration by restoring both shape and size of the organ.^[50] In the liver, large areas of the tissues are formed but for the formation of new cells there must be sufficient amount of material so the circulation of the blood becomes more active.^[51]

This is predominantly due to the hepatocytes re-entering the cell cycle. That is, the hepatocytes go from the quiescent G0 phase to the G1 phase and undergo mitosis. This process is activated by the p75 receptors.^[52] There is also some evidence of bipotential stem cells, called hepatic oval cells or ovalocytes (not to be confused with oval red blood cells of ovalocytosis), which are thought to reside in the canals of Hering. These cells can differentiate into either hepatocytes or cholangiocytes. Cholangiocytes are the epithelial lining cells of the bile ducts.^[53] They are cuboidal epithelium in the small interlobular bile ducts, but become columnar and mucus secreting in larger bile ducts approaching the porta hepatis and the extrahepatic ducts.

Scientific and medical works about liver regeneration often refer to the Greek Titan Prometheus who was chained to a rock in the Caucasus where, each day, his liver was devoured by an eagle, only to grow back each night. The myth suggests the ancient Greeks may have known about the liver’s remarkable capacity for self-repair.^[54]

Liver transplantation

Human liver transplants were first performed by Thomas Starzl in the United States and Roy Calne in Cambridge, England in 1963 and 1967, respectively.

Liver transplantation is the only option for those with irreversible liver failure. Most transplants are done for chronic liver diseases leading to cirrhosis, such as chronic hepatitis C, alcoholism, autoimmune hepatitis, and many others. Less commonly, liver transplantation is done for fulminant hepatic failure, in which liver failure occurs over days to weeks.

Liver allografts for transplant usually come from donors who have died from fatal brain injury. Living donor liver transplantation is a technique in which a portion of a living person's liver is removed and used to replace the entire liver of the recipient. This was first performed in 1989 for pediatric liver transplantation. Only 20 percent of an adult's liver (Couinaud segments 2 and 3) is needed to serve as a liver allograft for an infant or small child.

More recently, adult-to-adult liver transplantation has been done using the donor's right hepatic lobe, which amounts to 60 percent of the liver. Due to the ability of the liver to regenerate, both the donor and recipient end up with normal liver function if all goes well. This procedure is more controversial, as it entails performing a much larger operation on the donor, and indeed there have been at least two donor deaths out of the first several hundred cases. A recent publication has addressed the problem of donor mortality, and at least 14 cases have been found.^[55] The risk of postoperative complications (and death) is far greater in right-sided operations than that in left-sided operations.

With the recent advances of noninvasive imaging, living liver donors usually have to undergo imaging examinations for liver anatomy to decide if the anatomy is feasible for donation. The evaluation is usually performed by multidetector row computed tomography (MDCT) and magnetic resonance imaging (MRI). MDCT is good in vascular anatomy and volumetry. MRI is used for biliary tree anatomy. Donors with very unusual vascular anatomy, which makes them unsuitable for donation, could be screened out to avoid unnecessary operations.

• MDCT image. Arterial anatomy contraindicated for liver donation

• MDCT image. Portal venous anatomy contraindicated for liver donation

• MDCT image. 3D image created by MDCT can clearly visualize the liver, measure the liver volume, and plan the dissection plane to facilitate the liver transplantation procedure.

• Phase contrast CT image. Contrast is perfusing the right liver but not the left due to a left portal vein thrombus.

Society and culture

In Greek mythology, Prometheus was punished by the gods for revealing fire to humans, by being chained to a rock where a vulture (or an eagle) would peck out his liver, which would regenerate overnight. (The liver is the only human internal organ that actually can regenerate itself to a significant extent.) Many ancient peoples of the Near East and Mediterranean areas practiced a type of divination called haruspicy, where they tried to obtain information by examining the livers of sheep and other animals.

In Plato, and in later physiology, the liver was thought to be the seat of the darkest emotions (specifically wrath, jealousy and greed) which drive men to action.^[56] The Talmud (tractate Berakhot 61b) refers to the liver as the seat of anger, with the gallbladder counteracting this.

The Persian, Urdu, and Hindi languages (جگر or जिगर or jigar) refer to the liver in figurative speech to indicate courage and strong feelings, or "their best"; e.g., "This Mecca has thrown to you the pieces of its liver!".^[57] The term jan e jigar, literally "the strength (power) of my liver", is a term of endearment in Urdu. In Persian slang, jigar is used as an adjective for any object which is desirable, especially women. In the Zulu language, the word for liver (isibindi) is the same as the word for courage.

The legend of Liver-Eating Johnson says that he would cut out and eat the liver of each man killed after dinner.

In the motion picture The Message, Hind bint Utbah is implied or portrayed eating the liver of Hamza ibn ‘Abd al-Muttalib during the Battle of Uhud. Although there are narrations that suggest that Hind did "taste", rather than eat, the liver of Hamza, the authenticity of these narrations has to be questioned.

On November 26, 1987, the city of Ferrol, Spain, inaugurated what is believed to be the only monument to the liver in the world. The then - major, Jaime Quintanilla, also happened to be a doctor, and thought appropriate to promote the monument. At an approximate cost of $3.200, the monument stands in the village of Balón. A plaque reads (In Galician language, free translation): "The Liver [is the] basis of Life", and below "Through History, Mankind tried to cure all illness. By helping it on this duty, you are doing a great job. We are grateful for it".^[58]

Food

The liver of mammals, fowl, and fish are commonly eaten as food by humans. Domestic pig, ox, lamb, calf, chicken, and goose livers are widely available from butchers and supermarkets.

Liver can be baked, boiled, broiled, fried, stir-fried, or eaten raw (asbeh nayeh or sawda naye in Lebanese cuisine, liver sashimi). In many preparations, pieces of liver are combined with pieces of meat or kidneys, like in the various forms of Middle Eastern mixed grill (e.g. meurav Yerushalmi). Liver is often made into spreads. Well-known examples include liver pâté, foie gras, chopped liver, and leverpastej. Liver sausages such as Braunschweiger and liverwurst are also a valued meal. Liver sausages may also be used as spreads. A traditional South African delicacy, namely skilpadjies, is made of minced lamb's liver wrapped in netvet (caul fat), and grilled over an open fire.

Animal livers are rich in iron and vitamin A, and cod liver oil is commonly used as a dietary supplement. Traditionally, some fish livers were valued as food, especially the stingray liver. It was used to prepare delicacies, such as poached skate liver on toast in England, as well as the beignets de foie de raie and foie de raie en croute in French cuisine.^[59]

Other animals

The liver is found in all vertebrates, and is typically the largest visceral (internal) organ. Its form varies considerably in different species, and is largely determined by the shape and arrangement of the surrounding organs. Nonetheless, in most species it is divided into right and left lobes; exceptions to this general rule include snakes, where the shape of the body necessitates a simple cigar-like form. The internal structure of the liver is broadly similar in all vertebrates.^[60]

An organ sometimes referred to as a liver is found associated with the digestive tract of the primitive chordate Amphioxus. Although it performs many functions of a liver, it is not considered a true liver but a homolog of the vertebrate liver.^[61][62][63] The amphioxus hepatic caecum produces the liver-specific proteins vitellogenin, antithrombin, plasminogen, alanine aminotransferase, and insulin/Insulin-like growth factor (IGF)^[64]

Additional images

• View of the various organs and blood-vessels in proximity with liver.

• Liver lifted to show gall bladder and stomach in situ.

• Cross section showing the liver as the large brown mass in the left of the images, right of the individual.

• Cross section of an inferior portion of the liver, showing gallbladder and various structures.

• Human liver. Visceral surface of liver.

• Human liver. Horizontal section to newborn

• Showing ligaments and bare area

• Liver

See also

• Artificial liver
• Enterohepatic circulation
• Hepatectomy
• Liver shot (martial arts strike)
• Polycystic liver disease
• Portacaval anastomosis
• Portal hypertension

References

External links

• Liver at the Open Directory Project.
• VIRTUAL Liver – online learning resource
• Liver enzymes