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Hallmarks of peripheral nerve function in bone regeneration

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• Review Article
• Open access
• Published: 05 January 2023

Hallmarks of peripheral nerve function in bone regeneration

• Ranyang Tao, 
• Bobin Mi, 
• Yiqiang Hu, 
• Sien Lin, 
• Yuan Xiong, 
• Xuan Lu, 
• Adriana C. Panayi, 
• Gang Li & 
• Guohui Liu 

Bone Research volume 11, Article number: 6 (2023) Cite this article

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Abstract

Skeletal tissue is highly innervated. Although different types of nerves have been recently identified in the bone, the crosstalk between bone and nerves remains unclear. In this review, we outline the role of the peripheral nervous system (PNS) in bone regeneration following injury. We first introduce the conserved role of nerves in tissue regeneration in species ranging from amphibians to mammals. We then present the distribution of the PNS in the skeletal system under physiological conditions, fractures, or regeneration. Furthermore, we summarize the ways in which the PNS communicates with bone-lineage cells, the vasculature, and immune cells in the bone microenvironment. Based on this comprehensive and timely review, we conclude that the PNS regulates bone regeneration through neuropeptides or neurotransmitters and cells in the peripheral nerves. An in-depth understanding of the roles of peripheral nerves in bone regeneration will inform the development of new strategies based on bone-nerve crosstalk in promoting bone repair and regeneration.

초록

골격 조직은 고도로 신경이 분포되어 있습니다. 

최근 뼈에서 다양한 유형의 신경이 확인되었지만, 

뼈와 신경 사이의 누화는 여전히 불분명합니다. 

이 리뷰에서는 

부상 후 뼈 재생에서 말초신경계(PNS)의 역할에 대해 

간략하게 설명합니다. 

먼저 양서류에서 포유류에 이르는 다양한 종에서 

조직 재생에 있어 신경의 보존된 역할을 소개합니다. 

그런 다음 

생리적 조건, 골절 또는 재생에 따른 골격계에서 

PNS의 분포를 제시합니다. 

또한 

뼈 미세 환경에서 PNS가 

골계 세포, 혈관계 및 면역 세포와 소통하는 방식을 요약합니다. 

이러한 종합적이고 시의적절한 검토를 바탕으로 우리는 

PNS가 

말초 신경의 신경 펩타이드 또는 신경 전달 물질과 세포를 통해 

뼈 재생을 조절한다는 결론을 내렸습니다. 

뼈 재생에서 

말초 신경의 역할에 대한 심층적인 이해는 

뼈 회복과 재생을 촉진하는 뼈-신경 누화를 기반으로 한 

새로운 전략 개발에 도움이 될 것입니다.

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Introduction

Different species have developed unique biological functions that allow them to survive in specific environments through evolution. The ability of most organisms to regenerate or repair tissue after injury or loss has also been significantly impacted by natural selection. In contrast to anthropocentric thinking, animals that possess the capacity for regeneration did not seem to obtain enough evolutionary advantages to make this trait highly conserved. The ability to regenerate is widely but not uniformly distributed among different species.1 Some organisms, such as teleost fishes, can regenerate all severed appendages and even vital organs, such as the heart, while many other species, including humans, cannot.2,3,4

In addition to stem cells, which are well-known players, many animal studies of tissue regeneration have suggested the important roles of peripheral nerves in the regeneration of various tissues. Peripheral nerves can be functionally divided into three categories: the autonomic nervous system (ANS), the somatic nervous system, and the enteric nervous system.5 Peripheral nerves classically function as links between central and peripheral organs through ligands secreted by terminal axons, establishing a pathway for central-peripheral communication and allowing the central nervous system (CNS) to perceive the external environment. Numerous studies have demonstrated that the ANS and somatic nervous system may be linked to the regeneration process, while the enteric nervous system has been recently shown to play an important role in the regulation of intestinal homeostasis and mucosal regeneration.6,7 Nerve fibers in each fascicle are protected by a connective tissue called endoneurium, which contains many cells, such as fibroblasts, macrophages, and vasculature-associated cells.8 There is increasing interest in the contributions of resident cells in nerves, Schwann cells (SCs), and endoneurial mesenchymal cells, as well as the nonclassical functions of peripheral nerves, such as the regulation of homeostasis,9,10,11,12 effects on development,13,14 and roles in tissue regeneration.15,16,17,18

소개

생물 종마다 진화를 통해 특정 환경에서 생존할 수 있는 독특한 생물학적 기능을 개발해 왔습니다. 대부분의 유기체가 손상이나 손실 후 조직을 재생하거나 복구하는 능력도 자연 선택의 영향을 크게 받았습니다. 인간 중심적 사고와 달리, 재생 능력을 가진 동물은 이 특성이 고도로 보존될 만큼 충분한 진화적 이점을 얻지 못한 것으로 보입니다. 재생 능력은 여러 종에 걸쳐 광범위하지만 균일하게 분포되어 있지는 않습니다.1 텔레오스트 물고기와 같은 일부 생물은 절단된 부속기관은 물론 심장과 같은 중요한 장기까지 재생할 수 있지만 인간을 포함한 다른 많은 종은 그렇지 못합니다.2,3,4

잘 알려진 줄기세포 외에도

조직 재생에 대한 많은 동물 연구에서

말초신경이 다양한 조직의 재생에 중요한 역할을 한다는 사실이 밝혀졌습니다.

말초 신경은 기능적으로

자율 신경계(ANS),

체성 신경계,

장 신경계의 세 가지 범주로 나눌 수 있습니다.5

 autonomic nervous system (ANS),

the somatic nervous system, and

the enteric nervous system.

말초 신경은

말단 축삭에서 분비되는 리간드를 통해 중추와 말초 기관을 연결하여

중추-말초 통신 경로를 설정하고

중추 신경계(CNS)가 외부 환경을 인지할 수 있도록 하는 기능을 합니다.

수많은 연구를 통해

ANS와 체성 신경계가

재생 과정과 관련이 있을 수 있다는 사실이 입증되었으며,

최근에는 장 신경계가 장의 항상성 조절과 점막 재생에 중요한 역할을 하는 것으로 밝혀졌습니다.6,7

각 신경 섬유는

섬유아세포, 대식세포 및 혈관 관련 세포와 같은 많은 세포를 포함하는

엔도네리움이라는 결합 조직에 의해 보호됩니다.8

항상성 조절,9,10,11,12

발달에 미치는 영향,13,14

조직 재생에서의 역할과 같은 말초 신경의 비고전적 기능뿐만 아니라

신경의 상주 세포, 슈반 세포(SC) 및 척수 내 중간엽 세포의 기여에 대한

관심이 증가하고 있습니다.15,16,17,18

The role of peripheral nerves in regeneration was first discovered in salamander limb regeneration,19 which is one of the most common models in regenerative medicine.20 Salamander limb regeneration is often considered to reproduce part of the developmental process. The process of regeneration is initiated by wound closure through the wound epithelium (WE). Under the newly formed WE, stump cells dedifferentiate and proliferate to form a blastema, which is a collection of various types of stem cells or progenitor cells. Later, under precise control, the distal blastema forms the apical ectodermal cap and gradually differentiates into a new limb.20,21 As the close connection between limb regeneration and the peripheral nervous system (PNS) in the salamander was gradually explored,21,22 revealing that reinnervation is indispensable for the restoration of lost or damaged tissues, more attention has been given to the role of the PNS in regeneration, particularly in humans.

Although many mammals, including humans, lack the ability to reconstruct a severed limb, their bone tissue can recover from trauma without scar formation. Bone fracture healing proceeds through four phases: hematoma, soft callus, hard callus, and hard callus remodeling.23 Bone healing starts with inflammation resulting from high-energy trauma, and immediate activation of the coagulation cascade leads to hematoma formation at the injured site. With the gradual resolution of inflammation, intramembranous ossification occurs at the periosteum where there is a good blood supply close to the fracture site, whereas areas under hypoxic conditions undergo endochondral ossification. The differentiation of mesenchymal stromal cells (MSCs) from marrow, muscle, and especially the periosteum into bone-lineage cells drives the formation of callus. Finally, the dynamic balance of osteoblast and osteoclast activity remodels newly formed woven bone into lamellar bone. Bones are richly innervated by peripheral nerves, and parallel findings on the role of the PNS in limb regeneration in distant spices and bone regeneration point to the common role of nerves in regeneration.24,25 Despite the fact that the role of the PNS in many other processes associated with bone metabolism has not been fully characterized, the inevitable question now applies to bone regeneration: how does communication occur between the PNS and other tissues in the bone regenerative microenvironment?

재생에서 말초 신경의 역할은

재생 의학에서 가장 일반적인 모델 중 하나인

도롱뇽 사지 재생에서 처음 발견되었습니다.19

도롱뇽 사지 재생은 종종 발달 과정의 일부를 재현하는 것으로 간주됩니다.20

재생 과정은 상처 상피(WE)를 통한 상처 봉합으로 시작됩니다.

새로 형성된 WE 아래에서 그루터기 세포는 분화 및 증식하여 다양한 유형의 줄기세포 또는 전구세포의 집합체인 모세포를 형성합니다. 이후, 원위 배반포는 정밀한 제어 하에 정단 외배엽 뚜껑을 형성하고 점차 새로운 사지로 분화합니다.20,21 도롱뇽에서 사지 재생과 말초 신경계(PNS) 사이의 긴밀한 연관성이 점차 밝혀지면서,21,22 재신경이 손실되거나 손상된 조직의 회복에 필수적이라는 사실이 밝혀지면서 특히 인간에서 재생에서 PNS의 역할에 더 많은 관심이 주어지고 있습니다.

인간을 포함한 많은 포유류는

절단된 팔다리를 재건하는 능력이 부족하지만,

뼈 조직은 흉터 형성 없이 외상으로부터 회복할 수 있습니다.

골절 치유는

혈종, 연성 캘러스, 경성 캘러스, 경성 캘러스 리모델링의 네 단계를 거쳐 진행됩니다.23

hematoma,

soft callus,

hard callus, and

hard callus remodeling

뼈 치유는

고에너지 외상으로 인한 염증으로 시작되며

응고 캐스케이드의 즉각적인 활성화는

손상 부위에 혈종 형성으로 이어집니다.

염증이 점진적으로 해결되면서

골절 부위와 가까운 혈액 공급이 양호한 골막에서는

골막 내 골화가 일어나고

저산소 상태의 부위는 골내막 골화가 일어납니다.

골수, 근육, 특히 골막에서 중간엽 간엽 세포(MSC)가

골계 세포로 분화하면

캘러스 형성이 촉진됩니다.

마지막으로

조골세포와 파골세포 활동의 역동적인 균형이

새로 형성된 뼈를 라멜라 뼈로 리모델링합니다.

뼈는

말초 신경에 의해 풍부하게 신경을 공급받으며,

 distant spices와 뼈 재생에서 사지 재생에서 PNS의 역할에 대한 병행 연구 결과는

재생에서 신경의 공통된 역할을 지적합니다.24,25

뼈 대사와 관련된 다른 많은 과정에서

PNS의 역할이 완전히 특성화되지 않았음에도 불구하고

이제 뼈 재생에 적용되는 불가피한 질문은

뼈 재생 미세 환경에서 PNS와 다른 조직 간에 어떻게 통신이 이루어지느냐는 점입니다.

In this review, we focus on the conserved role of nerves in regeneration during evolution and summarize the innervation of bone under normal physiological conditions and during bone regeneration following trauma. We emphasize the presence of neuro-skeletal, neurovascular and neuroimmune interactions at different stages of bone regeneration and discuss the possible nerve-associated cellular and molecular mechanisms involved in osteogenesis and other processes that are essential for bone formation. We address the limitations and challenges in current studies with the hope of inspiring further research.

이 리뷰에서는 

진화 과정에서 재생에 있어 신경의 보존된 역할에 초점을 맞추고 

정상적인 생리적 조건과 외상 후 뼈 재생 과정에서 뼈의 신경 분포에 대해 요약합니다. 

뼈 재생의 여러 단계에서 

신경 골격, 신경 혈관 및 신경 면역 상호 작용의 존재를 강조하고 

골 형성 및 뼈 형성에 필수적인 기타 과정에 관여하는 

가능한 신경 관련 세포 및 분자 메커니즘에 대해 논의합니다. 

또한 

현재 연구의 한계와 과제를 짚어보고 

향후 연구에 영감을 불어넣고자 합니다.

Function of peripheral nerves in tissue regeneration

Because the regeneration of amputated limbs in salamanders, from the blastema to the entire appendage, reflects the ideal outcome of regenerative medicine, efforts have been made to investigate whether the nerve-dependent mechanism is widespread in nature and to identify the animal model that is most similar to humans. In a salamander study, regeneration of the upper limb was inhibited by denervation at the brachial plexus level.26 Diverting nerves toward the damaged site could promote limb regeneration27 and even the growth of supernumerary limbs.28 It is noteworthy that the extent of denervation positively correlated with the impairment of limb regeneration,21 suggesting that peripheral nerves may be involved in the precise regulation of limb regeneration.

Regarding the mechanisms by which peripheral nerves regulate salamander limb regeneration, diffusible nerve factors were shown to cross the filter and promote blastema cell proliferation.29 In response to initial nerve injury signals, SCs undergo phenotypic changes, downregulating myelin proteins, such as Krox20, Sox10, and neuregulin 1. Similar to their progenitors, negative regulators of myelination and growth-promoting proteins, such as Notch and c-Jun, are upregulated in SCs. These changes facilitate the transition of SCs from typical peripheral glial cells to repair cells. Together with blastema-infiltrating nerve fibers, repair SCs release a variety of molecules in the microenvironment of the blastema. Although poorly understood, many diffusible nerve factors have been shown to regulate regenerative processes in the salamander, including substance P (SP),30,31 platelet-derived growth factor (PDGF),32 fibroblast growth factors, bone morphogenetic protein (BMP),33,34 glial growth factor,35 newt anterior gradient (nAG),36 transferrin,37 and neuregulin.38,39 These paracrine factors are produced by neurons or repair SCs and provide signals to immune cells or stem/precursor cells to support regeneration.40

The participation of peripheral nerves in regeneration is not, however, limited to salamanders or amphibians but is found in many other species, from lower organisms such as sea anemones,41 hydras (Cnidaria),42 planarians (Platyhelminthes),43 and starfish (Echinodermata),44 to vertebral organisms such as zebrafish,45 which possess the capacity for regeneration under neural effects (Fig. 1). Notably, the existence of species such as Placozoa and Porifera, which have the ability to regenerate without the nervous system, is coincident with the observation of the aneurogenic limb, which regenerates without a nerve supply but develops nerve-dependent regeneration after nerve transplantation and innervation.22 New findings in mammals are consistent with previous studies. For example, MRL/MpJ mice can regenerate injured ear tissue through blastema-like structures, while denervation inhibits the formation of the blastema.46 Furthermore, in murine digit tip regeneration, SCs in injured nerves have been shown to dedifferentiate and promote blastema proliferation in a paracrine manner.47 The process from blastema formation to appendage regrowth also requires complex regulation, such as cell pattern and polarity,48 which depends on the location (distal or proximal, dorsal or ventral) of cells within the newly formed tissue. Patterning defects have also been noted in denervated and regenerating murine digits.17 Taken together, these results indicate the widespread participation of peripheral nerves in mammalian tissue regeneration.

조직 재생에서 말초 신경의 기능

도롱뇽의 절단된 사지 재생은

배반포에서 전체 부속기에 이르기까지 재생 의학의 이상적인 결과를 반영하기 때문에

신경 의존 메커니즘이 자연에 널리 퍼져 있는지 조사하고

인간과 가장 유사한 동물 모델을 식별하기 위한 노력이 이루어졌습니다.

도롱뇽 연구에서 상지 재생은

상완 신경총 수준의 탈신경화에 의해 억제되었습니다.26

손상된 부위로 신경을 돌리면

사지 재생27 및 상지의 성장까지 촉진할 수 있습니다.28

탈신경화의 정도가 사지 재생의 손상과 양의 상관관계가 있다는 것은 주목할 만한 사실이며,21

말초 신경이 사지 재생의 정밀한 조절에 관여할 수 있음을 시사하는 것입니다.

말초 신경이

도롱뇽 사지 재생을 조절하는 메커니즘과 관련하여

확산성 신경 인자가 필터를 통과하여

모세포 증식을 촉진하는 것으로 나타났습니다.29

초기 신경 손상 신호에 반응하여

SC는 표현형 변화를 겪으며 Krox20, Sox10, 뉴레귤린 1과 같은 미엘린 단백질이 하향 조절됩니다.

전구세포와 마찬가지로 SC에서 Notch 및 c-Jun과 같은 미엘린 및 성장 촉진 단백질의 음성 조절 인자가 상향 조절되고, 미엘린과 성장 촉진 인자의 음성 조절 인자가 상향 조절됩니다. 이러한 변화는 SC가 전형적인 말초 신경교 세포에서 복구 세포로 전환하는 것을 촉진합니다. 수리 SC는 아세포종에 침윤하는 신경 섬유와 함께 아세포종의 미세 환경에서 다양한 분자를 방출합니다. 잘 알려져 있지는 않지만, 물질 P(SP),30,31 혈소판 유래 성장 인자(PDGF),32 섬유아세포 성장 인자, 골 형성 단백질(BMP),33,34 신경교 성장 인자,35 뉴런 전구배(nAG),36 트랜스페린,37 및 뉴레귤린 등 많은 확산 가능한 신경 인자들이 도롱뇽에서 재생 과정을 조절하는 것으로 나타났습니다.38,39 이러한 파라크린 인자는 뉴런 또는 수리 SC에 의해 생성되며 면역 세포 또는 줄기/전구세포에 신호를 제공하여 재생을 지원합니다.40

그러나 말초 신경의 재생 참여는도롱뇽이나 양서류에 국한된 것이 아니라 말미잘,41 히드라(크니다리아),42 평면동물(플라티헬민테스),43 불가사리(극피동물 ),44 제브라피쉬와 같은 척추 생물,45 신경 효과 하에서 재생 능력을 가진 척추 생물에 이르기까지 많은 다른 종에서 발견됩니다(그림 1).

특히 신경계 없이도 재생할 수 있는 능력을 가진 플라코조아 및 포리페라와 같은 종의 존재는 신경 공급 없이 재생하지만 신경 이식 및 신경 분포 후 신경 의존적 재생을 하는 무신경성 사지의 관찰과 일치합니다.22

포유류의 새로운 발견은 이전 연구와 일치합니다. 예를 들어, MRL/MpJ 마우스는 손상된 귀 조직이 모세포종과 유사한 구조를 통해 재생되는 반면 탈신경은 모세포종의 형성을 억제합니다.46 또한, 쥐의 손가락 끝 재생에서 손상된 신경의 SC가 파라크린 방식으로 모세포종의 증식을 분화 및 촉진하는 것으로 나타났습니다.47 모세포종 형성에서 부속기 재성장에 이르는 과정에는 세포 패턴 및 극성과 같은 복잡한 조절이 필요하며,48 이는 새로 형성된 조직 내 세포의 위치(원위 또는 근위, 등 또는 배)에 따라 달라집니다. 패턴 결함은 탈신경화 및 재생 중인 쥐의 손가락에서도 발견되었습니다.17 이러한 결과를 종합하면 포유류 조직 재생에 말초 신경이 광범위하게 관여하고 있음을 알 수 있습니다.

Fig. 1

Distribution of regeneration and its nerve dependence in animals from lower to higher species. This phylogenetic tree topology contains almost all animal species. The yellow arrow at the bottom from left to right indicates the gradient from animals that emerged earlier in evolutionary history (lower organisms) to those that evolved later (higher organisms). The distribution of regeneration capacity in most animal phyla could be confirmed in at least one member. “Presence of regeneration” means that there is at least one verified taxon in the corresponding phylum that has the ability to regenerate complex parts of the body; it does not refer to all the taxa included. “Presence of nerve dependence” means that there is at least one well-substantiated report indicating the function of the nervous system in regeneration. “No documentation” means that more reliable studies are needed on the topic. Tree topologies and regeneration data are based on ref. 292 Data on nerve dependence are based on refs. 21,22,41,42,43,44,45,293,294,295,296

하등 동물에서 고등 동물에 이르는 동물의 재생 분포와 신경 의존성. 이 계통 발생 트리 토폴로지는 거의 모든 동물 종을 포함합니다. 왼쪽에서 오른쪽으로 아래쪽의 노란색 화살표는 진화 역사에서 일찍 출현한 동물(하등 생물)에서 나중에 진화한 동물(고등 생물)로의 그라데이션을 나타냅니다. 대부분의 동물 문에서 재생 능력의 분포는 적어도 한 개체에서 확인할 수 있습니다. “재생 능력의 존재"는 신체의 복잡한 부분을 재생할 수 있는 능력이 있는 것으로 확인된 분류군이 해당 문에 하나 이상 존재한다는 것을 의미하며, 포함된 모든 분류군을 의미하는 것은 아닙니다. “신경 의존성 존재"는 재생에 있어 신경계의 기능을 나타내는 잘 입증된 보고서가 하나 이상 있음을 의미합니다. “문서 없음"은 해당 주제에 대해 더 신뢰할 수 있는 연구가 필요하다는 의미입니다. 트리 토폴로지 및 재생 데이터는 참고 문헌292 신경 의존성에 대한 데이터는 참고 문헌을 기반으로 합니다. 21,22,41,42,43,44,45,293,294,295,296

Advances in the understanding of tissue regeneration in other species have shed light on regeneration mechanisms in mammals. nAG, which is mainly produced by repair SCs during salamander limb regeneration, binds to its receptor Prod1 to stimulate blastema cells to enter the S phase of the cell cycle and promote blastema expansion.36 The administration of nAG rescues 50% of the effect of denervation on salamander limb regeneration.36 Unfortunately, although it is heralded as the key to the field of regenerative medicine, nAG has no orthologous protein in humans.49 The closest proteins in humans are anterior gradient protein 2 (AGR2) and AGR3, but their potential role in regeneration remains unclear, as these factors lack the features of secreted proteins.49 Nevertheless, cells in the blastema were once considered to be multipotent and homogeneous based on studies of salamander regeneration.50 Genetic lineage tracing and single-cell transcriptomic profiling of mammalian digit regeneration, however, have shown that the heterogeneous blastema consists of many cell types.51,52 Later studies indicated that the origin cells of the blastema were developmental lineage-restricted, which is prevented across germline lineages51,53 but is relatively flexible in the consequent generated mesenchymal lineage,54 suggesting that the newly formed tissue differentiated from blastema cells depending on their respective origin and regenerative microenvironment. Distinct from the paracrine pathway, most endoneurial mesenchymal cells in peripheral nerves have multipotential differentiation abilities, as shown by upregulated expression‎ of genes such as Aldh1a2, Col11a1, Cthrc1, Inhbb, Kng2, and Wif1 and downregulated expression‎ of genes related to connective tissue after nerve injury. These neural crest-derived cells (NCCs) not only contribute to blastema formation but also subsequently differentiate into dermis or bone in response to specific environmental cues.55

Overall, studies on both mammals and phylogenetically distant animals, such as amphibians, show how peripheral nerves can regulate regeneration: (1) the secretion of neuropeptides, neurotransmitters, and other neural molecules21,56 and (2) the differentiation of stem/precursor-like cells and/or transdifferentiation from endoneurial mesenchymal cells in injured peripheral nerves.5

다른 종의 조직 재생에 대한 이해가 발전하면서 포유류의 재생 메커니즘이 밝혀졌습니다. 도롱뇽 사지 재생 과정에서 주로 수리 SC에 의해 생성되는 nAG는 수용체 Prod1과 결합하여 모세포가 세포 주기의 S 단계로 진입하도록 자극하고 모세포의 확장을 촉진합니다.36 nAG를 투여하면 도롱뇽 사지 재생에 대한 탈신경 효과의 50%가 회복됩니다.36 안타깝게도 재생 의학 분야의 핵심으로 예고되고 있지만 nAG는 인간에게 유사 단백질이 없습니다.49 인간에서 가장 가까운 단백질은 전방 경사 단백질 2(AGR2)와 AGR3이지만 이러한 인자들은 분비 단백질의 특징이 없기 때문에 재생에서 잠재적 역할은 아직 불분명합니다.49 그럼에도 불구하고 도롱뇽 재생에 대한 연구에 따르면 배반포의 세포는 한때 다능하고 동질적인 것으로 간주되었습니다.50 그러나 포유류 숫자 재생의 유전 계통 추적 및 단일 세포 전사체 프로파일링은 이질적인 배반포가 다양한 세포 유형으로 구성되어 있음을 보여주었습니다.51,52 이후 연구에 따르면 배반포의 기원 세포는 생식세포 계통51,53에서는 발달 계통이 제한되어 있지만 결과적으로 생성된 중간엽 계통에서는 상대적으로 유연하며,54 새로 형성된 조직은 각각의 기원 및 재생 미세 환경에 따라 배반포 세포로부터 분화되었음을 시사합니다. 파라크린 경로와는 달리 말초 신경의 대부분의 신경 내 중간엽 세포는 신경 손상 후 Aldh1a2, Col11a1, Cthrc1, Inhbb, Kng2, Wif1 과 같은 유전자의 발현이 상향 조절되고 결합 조직과 관련된 유전자의 발현이 하향 조절되는 것으로 볼 때 다중 잠재 분화 능력을 가지고 있습니다. 이러한 신경 볏 유래 세포(NCC)는 모세포종 형성에 기여할 뿐만 아니라 이후 특정 환경 신호에 반응하여 진피 또는 뼈로 분화합니다.55

전반적으로 포유류와 양서류와 같이 계통적으로 먼 동물에 대한 연구는 말초 신경이 어떻게 재생을 조절할 수 있는지 보여줍니다: (1) 신경 펩타이드, 신경 전달 물질 및 기타 신경 분자의 분비21,56 그리고 (2) 손상된 말초 신경에서 줄기/전구체 유사 세포의 분화 및/또는 내신경 중간엽 세포의 전분화입니다.5

Distribution of peripheral nerves in the skeletal system

The afferent nerves of the peripheral system are collectively known as sensory nerves. The efferent nerves consist of motor nerves and autonomic nerves, which can be further categorized into the sympathetic nervous system (SNS) and the parasympathetic nervous system (PSNS) (Fig. S1). Sensory nerves extend from their cell bodies in the dorsal root ganglia (DRGs) of the spinal cord, and cranial bone is innervated by sensory nerves emanating from cranial nerve ganglia, such as the trigeminal ganglion. Depending on their diameter and myelination, sensory nerves can also be classified into thin, nonmyelinated C fibers and myelinated A fibers.57,58 It has been shown that pain after bone fracture is mainly detected by Aδ fibers and C fibers59 because Aδ fibers and C fibers account for almost all sensory nerves that innervate bone.60,61,62 C fibers can be further divided into peptidergic and nonpeptidergic fibers, which can transduce noxious chemical and thermal stimulation.57 Postganglionic fibers of the ANS are similar to C fibers, as they are thin and nonmyelinated.63

Peripheral innervation in the skeletal system has gradually been outlined using immunoreactivity to biomarkers of anabolic processes of postganglionic representative neurotransmitters (Fig. 2a, b). The distribution of the SNS in bones can be visualized through norepinephrine (NE), which is synthesized from the amino acid tyrosine by two important enzymes: tyrosine hydroxylase (TH) and dopamine β-hydroxylase.64,65 Neuropeptide Y (NPY) is mainly released by sympathetic terminals and accompanied in the periphery by NE,66 which is associated with NPY on SNS visualization. The location of acetylcholine (ACh) in the vesicular ACh transporter (VAChT) and choline acetyltransferase (ChAT) allows mapping of PSNS distribution.67,68 Major sensory neurotransmitters, such as calcitonin gene-related peptide (CGRP) and SP, can be used to identify peptidergic sensory nerves because of their relatively exclusive origins.69,70,71,72 Other primary molecules of sensory nerves, such as tropomyosin receptor kinase A (TrkA), neurofilament 200, and isolectin B4, are biomarkers of different sensory lineages (Fig. 2c).73,74,75 It has been reported that the proportions of CGRP+ peptidergic sensory axons and TH+ sympathetic adrenergic axons in the total nerve population innervating the skeleton were at least 20%–30% and 25%–50%, respectively.76 Reliable characterization of non‐peptidergic sensory axons that innervate bone is needed.

골격계에서 말초 신경의 분포

말초 신경의 구심성 신경은 통칭하여 감각 신경이라고 합니다.

구심성 신경은 운동 신경과 자율 신경으로 구성되며,

다시 교감 신경계(SNS)와 부교감 신경계(PSNS)로 분류할 수 있습니다(그림 S1).

감각 신경은 척수의 등쪽 뿌리 신경절(DRG)에 있는 세포체에서 뻗어나가고, 두개골은 삼차 신경절과 같은 뇌신경절에서 나오는 감각 신경에 의해 자극을 받습니다. 감각 신경은 직경과 수초화에 따라 가늘고 비수초화된 C 섬유와 수초화된 A 섬유로 분류할 수도 있습니다.57,58 골절 후 통증은 주로 Aδ 섬유와 C 섬유59 에 의해 감지되는 것으로 나타났는데, 이는 Aδ 섬유와 C 섬유가 뼈에 신경을 전달하는 거의 모든 감각 신경을 차지하기 때문입니다.60,61,62 C 섬유는 유해한 화학적 및 열 자극을 전달할 수있는 펩티더 성 및 비 펩티더 성 섬유로 더 나눌 수 있습니다 .57 ANS의 신경절 후 섬유는 얇고 비 수초화되어 있기 때문에 C 섬유와 유사합니다 .63

골격계의 말초 신경 분포는 신경절 후 대표적 신경전달물질의 동화작용 바이오마커에 대한 면역 반응성을 사용하여 점차 윤곽이 드러나고 있습니다(그림 2a, b). 뼈에서 SNS의 분포는 티로신 하이드 록실 라제 (TH)와 도파민 β- 하이드 록실 라제라는 두 가지 중요한 효소에 의해 아미노산 티로신에서 합성되는 노르 에피네프린 (NE)을 통해 시각화 할 수 있습니다 .64,65 신경 펩티드 Y (NPY)는 주로 교감 말단에 의해 방출되고 말초에서 NE,66 NPY와 동반되어 SNS 시각화에서 연관되어 있습니다. 소포 ACh 수송체(VAChT)와 콜린 아세틸 트랜스퍼라제(ChAT)에서 아세틸콜린(ACh)의 위치는 PSNS 분포의 매핑을 가능하게 합니다.67,68 칼시토닌 유전자 관련 펩티드(CGRP)와 SP 같은 주요 감각 신경전달물질은 상대적으로 배타적인 기원으로 인해 펩티드 감각 신경을 확인하는 데 사용할 수 있습니다.69,70,71,72 트로포미오신 수용체 키나아제 A(TrkA), 신경섬유 200, 이소렉틴 B4와 같은 감각 신경의 다른 주요 분자는 다양한 감각 계통의 바이오마커입니다(그림 2c).73,74,75 골격을 자극하는 전체 신경 집단에서 CGRP+ 펩티드 감각 축삭과 TH+ 교감 아드레날린 축삭의 비율은 각각 최소 20%-30% 및 25%-50%인 것으로 보고되었습니다.76 뼈에 신경을 전달하는 비펩티더성 감각 축삭에 대한 신뢰할 수 있는 특성화가 필요합니다.

Fig. 2

Main biomarkers of the ANS and sensory nerves. a Norepinephrine (NE) is synthesized from tyrosine by a multienzyme pathway. Tyrosine hydroxylase (TH) converts tyrosine to L-DOPA. L-Aromatic amino acid decarboxylase (AADC) converts L-DOPA into dopamine, which is finally hydroxylated by DA-β-hydroxylase (DBH) to produce NE. b Acetylcholine (ACh) is synthesized from choline and acetyl coenzyme A (acetyl-CoA) with catalysis by choline acetyltransferase (ChAT), and then vesicular ACh transporter (VAChT) stores ACh in vesicles. c Development of DRG sensory neurons. All DRG sensory neurons develop from neural crest cells and gradually differentiate into different lineages with sophisticated regulation, which is not fully understood. Finally, after progressive diversification, these immature neurons develop into various sensory neurons that transduce different kinds of sensation, including mechanoreceptors, proprioceptors, nociceptors, thermoreceptors and pruriceptors (sensitive to histamine-independent itch). The length of short vertical lines marked with specific biomarkers on the right corresponds to the different lineages on the left. The most representative expression‎ of this lineage during development is marked in boxes. The horizontal axis shows the relative development of DRG neurons, which means that Ngn1+ neurons are late developers. Dotted lines indicate deductions. Ngn1 Neurogenin-1, Ngn2 Neurogenin-2, TrkA Tropomyosin receptor kinase A, NF200 Neurofilament 200, IB4 Isolectin B4

The presence of the SNS and sensory nerves in the skeletal system has been visualized by immunolabeling techniques.61,71,72,77,78 However, since a group of postganglionic sympathetic neurons exhibits a cholinergic phenotype in bone,79,80 the accuracy of innervation of the PSNS in the bone as delineated by positive VAChT and ChAT immunoreactivity is compromised. Ingeniously, injection of a recombinant pseudorabies virus into the distal femoral metaphysis labels the intermediolateral column at the thoracic level with SNS innervation, as well as the intermediolateral column at the sacral spinal cord segment where PSNS preganglionic neurons are located, which establishes a strong connection between PSNS and bone innervation.81 Direct evidence tracing the autonomic postganglionic nerves in the bone to parasympathetic ganglia is expected to provide further support for their relationship.

The involvement of the PNS with the skeleton has been reported as early as embryonic development. Mesenchymal condensation directly differentiates into bone via intramembranous ossification during embryonic development to form flat bones, whereas during endochondral ossification, cartilaginous tissues form and are then replaced by mineralized bone.82 During the embryonic development of long bones in mice, endochondral ossification begins on approximately embryonic day 15 (E15), and secondary ossification occurs on approximately postnatal day 5 (P5).13,83 TrkA+ sensory nerves innervate the developing femur at the perichondrial region adjacent to sites of primary ossification on E14.5 and are present at the epiphyseal surface of the femur on P0.13 Nerve growth factor (NGF), which supports neuronal survival and guides axonal growth, is expressed in perichondrial cells as early as E14.5.13 The requirement of TrkA signaling in sensory nerves for the formation of primary and secondary ossification is further suggested by the reductions in innervation, angiogenesis, and osteogenesis resulting from the disruption of NGF-TrkA signaling.13 After birth, the density of nerves continues to increase in growing bones, but NPY + nerve fibers could not be detected until P4.84 In addition to long bone development, innervation also participates in osteogenesis through intramembranous ossification. The mandibular branch of the trigeminal nerve develops preferentially in the primordium of the lower jaw,85 and the ossification center of the mandible is just adjacent to the nerve bundle, extending along the inferior alveolar nerve.86 Genetic disruption of TrkA signaling in sensory nerves leads to early closure of cranial sutures.87

Generally, peripheral nerves are thought to accompany blood vessels,88 and this holds true in mature bones. Sensory nerves, as well as the SNS, parallel the vascular structures to reach bone as a mixture of motor, sensory and sympathetic nerves.89 The major nerves consist of mixed neural components innervating the periosteum in a meshwork pattern,71 particularly the inner cambium layer, which possesses a high cell density consisting mainly of periosteum-derived MSCs, osteoclasts and osteoblasts.90,91 Through nutrient canals, vertical Haversian canals, and transverse Volkmann’s canals, sensory and sympathetic nerve fibers penetrate into the cortical bone parallel to the vasculature and then into the bone marrow.92,93,94 Rodent studies have demonstrated that the periosteum has the highest density of innervation, followed by the bone marrow and mineralized cortical bone.76,77,92 Although there is a possibility that rodents and humans share a similar innervation pattern,95,96 consistent innervation density of the bone in humans has not been shown until recently.97 The significant predominance of CGRP+ nerves relative to TH+ nerves in the periosteum is reversed in bone marrow,76 indicating the different roles/mechanisms of sensory nerves and the SNS in regulating bone hemostasis and regeneration. When running parallel with the vasculature, the sensory nerves and SNS tend to run linearly or spirally around vessels, respectively.92,98 The distribution of peripheral nerves in bone constitutes the foundation of PNS-mediated regulation of the skeletal system. PSNS have been shown to exist in bone,81 but detailed and quantitative experiments are still lacking. Furthermore, the same subcompartment may exhibit heterogeneity in innervation when there is active metabolism, which is associated with more innervation, such as in epiphyseal trabecular bone.77 The physiological innervation of the PNS in different compartments of bone begins during embryonic development, facilitates the regulatory potential of peripheral nerves, and participates in various physiological or pathological processes in bone.

골격계에서 SNS와 감각 신경의 존재는 면역 표지 기술을 통해 시각화되었습니다 .61,71,72,77,78 그러나 신경절 후 교감 신경 세포 그룹이 뼈에서 콜린성 표현형을 나타 내기때문에79,80 양성 VAChT 및 ChAT 면역 반응성으로 묘사 된 뼈에서 PSNS의 신경 분포의 정확성이 손상됩니다. 독창적으로, 재조합 슈도라비 바이러스를 원위 대퇴골 형이상학에 주입하면 흉부 수준의 중측 요골과 PSNS 전신경절이 위치한 천추 척수 분절의 중측 요골에 PSNS 신경 분포가 표시되어 PSNS와 뼈 신경 분포 사이의 강력한 연결이 확립됩니다.81 뼈의 자율 신경절 후 신경과 부교감 신경절을 추적하는 직접적인 증거는 이들의 관계를 더욱 뒷받침 할 것으로 예상됩니다.

PNS와 골격의 관련성은 배아 발달 초기부터 보고되었습니다. 중간 엽 응축은 배아 발달 중에 막 내 골화를 통해 뼈로 직접 분화하여 평평한 뼈를 형성하는 반면, 연골 내 골화 중에는 연골 조직이 형성된 후 광물화 된 뼈로 대체됩니다 .82 생쥐에서 장골이 배아 발달하는 동안 약 배아 15일(E15)에 내연골 골화가 시작되고 약 출생 후 5일(P5)에 2차 골화가 발생합니다.13,83 TrkA+ 감각 신경은 E14.5에 1차 골화 부위와 인접한 골막 부위에서 발달 중인 대퇴골에 신경을 공급하고 P0에 대퇴골의 epiphyseal 표면에서 존재하며, 이는 생쥐의 골격이 형성되는 데 중요한 역할을 합니다. 13 신경세포의 생존을 지원하고 축삭 성장을 유도하는 신경 성장 인자(NGF)는 E14.5 초기에 골막 세포에서 발현됩니다.13 일차 및 이차 골화 형성에 대한 감각 신경에서 TrkA 신호의 필요성은 NGF-TrkA 신호의 중단으로 인한 신경 분포, 혈관 형성 및 골 형성의 감소를 통해 추가로 제시됩니다.13 출생 후 성장하는 뼈에서 신경의 밀도는 계속 증가하지만 NPY + 신경 섬유는 P4.84까지 감지 할 수 없었습니다. 긴 뼈 발달 외에도 신경 분포는 골막 내 골화를 통해 골 형성에 참여합니다. 삼차신경의 하악 분지는 아래턱의 원시골에서 우선적으로 발달하며,85 하악의 골화 중심은 신경 다발에 바로 인접하여 하치조 신경을 따라 연장됩니다.86 감각 신경에서 TrkA 신호의 유전적 중단은 두개골 봉합의 조기 폐쇄로 이어집니다.87

일반적으로 말초 신경은 혈관을 동반하는 것으로 생각되며,88 이는 성숙한 뼈에서도 마찬가지입니다. 감각 신경뿐만 아니라 SNS는 운동 신경, 감각 신경 및 교감 신경이 혼합되어 혈관 구조와 평행하게 뼈에 도달합니다.89 주요 신경은 골막을 그물망 패턴으로 자극하는 혼합 신경 성분으로 구성되어 있으며,71 특히 골막 유래 MSC, 파골 세포 및 조골 세포로 주로 구성된 높은 세포 밀도를 가진 내부 형성층은 골막에 분포합니다.90,91 영양관, 수직 하버시안관 및 횡단 볼크만관을 통해 감각 및 교감 신경 섬유는 혈관계와 평행하게 피질골로 침투한 다음 골수로 침투합니다.92,93,94 설치류 연구에 따르면 골막의 신경 분포 밀도가 가장 높고 골수와 광물화된 피질골이 그 뒤를 잇습니다.76,77,92 설치류와 인간이 유사한 신경 분포 패턴을 공유할 가능성이 있지만,95,96 인간에서 뼈의 일관된 신경 분포 밀도는 최근까지 밝혀지지 않았습니다.97 골막에서 TH+ 신경에 비해 CGRP+ 신경의 현저한 우세는 골수에서 역전되며,76 이는 뼈 지혈과 재생을 조절하는 감각 신경과 SNS의 역할/기전이 서로 다르다는 것을 나타냅니다. 감각 신경과 SNS는 혈관과 평행할 때 각각 혈관 주위를 선형 또는 나선형으로 흐르는 경향이 있습니다.92,98 뼈의 말초 신경 분포는 골격계의 PNS 매개 조절의 기초를 구성합니다. PSNS가 뼈에 존재하는 것으로 밝혀졌지만,81 세부적이고 정량적인 실험은 아직 부족합니다. 또한, 동일한 구획이라도 신진대사가 활발한 경우 신경 분포의 이질성을 보일 수 있으며, 이는 골격골과 같이 더 많은 신경 분포와 관련이 있습니다.77 뼈의 여러 구획에서 PNS의 생리적 신경 분포는 배아 발달 중에 시작되어 말초 신경의 조절 가능성을 촉진하고 뼈의 다양한 생리적 또는 병리학적인 과정에 참여합니다.

Distribution of peripheral nerves in the skeletal system following the fracture

Following injury, molecular and cellular changes are observed in the neuronal body, cells resident in peripheral nerves, and at the site of injury. These changes in peripheral nerves after bone fracture are prerequisites for the initiation of bone regeneration.

Changes in peripheral nerves after fracture

Bone fractures are common injuries caused by external forces or pathological changes that weaken the bone structure, and the PNS responds actively to the damage signal.99 The PNS interrupts synapses and switches to a regenerative state,100,101,102 reducing the production of neuropeptides for regeneration-associated metabolism, as shown by the downregulation of synthesis in the perikarya.103,104,105,106 However, neuropeptides, such as CGRP and SP, are thought to be increased in the fracture region.107,108 Apart from the fact that activation of the PNS directly contributes to the release of neurotransmitters,109 synthesis in injured axons (axonal synthesis) rather than the perikarya during regeneration partly accounts for the increase in neurotransmitters.110 When peripheral nerves are injured at a bone fracture site, injury signals travel in a retrograde manner along the proximal axon to the cell bodies to initiate regeneration.111 The distal axon undergoes Wallerian degeneration, in which the axon degenerates, myelin breaks down, the blood–nerve barrier is permeabilized, and the resultant myelin debris containing axonal growth inhibitory signals is cleared first by SCs and later by recruited macrophages.111,112 The roles of macrophages in peripheral nerve regeneration have been exhaustively reviewed recently.113 Other immune cells, such as mast cells, neutrophils, and T cells, are also recruited to the injured site as well as the distal stump and are involved in pain induction, but their role in nerve regeneration is still obscure.114 Regenerating proximal axons extend to the target organ following the guidance of SC basal lamina tubes, which are provisional channels formed by the proliferation of repair SCs.111 Delayed reinnervation of the target organ results in regeneration failure because of the degeneration of SC tubes.111

The mechanical deformation associated with bone fractures or defects activates the Aδ or C fibers, which transmit initial pain stimuli to the relevant cortical areas,115 and then central signals descend to the fracture site, resulting in local regulation such as the release of catecholamine by sympathetic arousal. Inflammation at the fracture site sensitizes the sensory nerves, which lowers the response threshold to noxious mechanical, chemical and thermal stimuli.109,116,117,118 There is a wide range of receptors at the terminals of sensory nerves that detect specific inflammatory mediators and growth factors,119 and the activation of these receptors triggers a series of downstream changes, such as the phosphorylation, gating, and upregulation of ion channels (e.g., Nav1.7, Nav1.8, Nav1.9, TRPV1, and TRPA1),109 leading to sensitization as well as further neurotransmitter release.109,120 Cytokines (histamine, TNF, IL-1β, IL-6, IL-17A), lipid mediators (prostaglandin E2 (PGE2), leukotriene B4), and growth factors (NGF, brain-derived neurotrophic factor (BDNF)) are produced mainly by mast cells, neutrophils, macrophages, and Th17 or γδT cells and contribute substantially to the sensitization of sensory nerves.121 For example, the binding of TNFα and its receptor (TNFα receptor 1, TNFR1) on the terminals phosphorylates Nav1.8 channels to facilitate channel opening.122 In short, Wallerian degeneration and inflammation are the primary responses of peripheral nerves during bone fracture.

골절 후 골격계에서 말초 신경의 분포

손상 후 신경세포, 말초 신경에 상주하는 세포 및 손상 부위에서 분자 및 세포 변화가 관찰됩니다. 이러한 골절 후 말초 신경의 변화는 뼈 재생을 시작하기 위한 전제 조건입니다.

골절 후 말초 신경의 변화

골절은 뼈 구조를 약화시키는 외력이나 병리학적인 변화로 인해 발생하는 흔한 손상으로, PNS는 손상 신호에 적극적으로 반응합니다.99 PNS는 시냅스를 중단하고 재생 상태로 전환합니다.100,101,102 골절 부위에서 합성의 하향 조절에서 볼 수 있듯이 재생 관련 대사를 위한 신경 펩타이드의 생산을 감소시킵니다.103,104,105,106 그러나 CGRP 및 SP와 같은 신경 펩타이드는 골절 부위에서 증가한다고 생각됩니다.107,108 PNS의 활성화가 신경전달물질의 방출에 직접적으로 기여한다는 사실 외에도,109 재생 중 말초가 아닌 손상된 축삭(축삭 합성)에서의 합성이 신경전달물질의 증가를 부분적으로 설명합니다.110 골절 부위에서 말초신경이 손상되면 손상 신호가 근위 축삭을 따라 세포체로 역행하여 재생을 시작하게 됩니다.111 원위 축삭은 축삭이 퇴화되고, 미엘린이 분해되고, 혈액-신경 장벽이 투과성화되고, 그 결과 축삭 성장 억제 신호를 포함하는 미엘린 파편이 SC에 의해 먼저 제거되고 나중에 모집된 대식세포에 의해 제거되는 월러리안 변성을 겪습니다.111,112 말초 신경 재생에서 대식세포의 역할은 최근에 철저히 검토되고 있습니다.113 비만세포, 호중구 및 T 세포와 같은 다른 면역 세포도 손상 부위뿐만 아니라 원위 그루터기에도 모집되어 통증 유발에 관여하지만 신경 재생에서의 역할은 아직 모호합니다.114 재생되는 근위 축삭은 수리 SC의 증식에 의해 형성되는 임시 채널인 SC 기저층 관의 안내에 따라 목표 기관으로 확장됩니다.111 목표 기관의 재신경화가 지연되면 SC 관의 퇴화로 인해 재생 실패가 초래됩니다.111

골절 또는 결함과 관련된 기계적 변형은 초기 통증 자극을 관련 피질 영역으로 전달하는 Aδ 또는 C 섬유를 활성화하고,115 중추 신호가 골절 부위로 내려가 교감 각성에 의한 카테콜아민 방출과 같은 국소 조절을 초래합니다. 골절 부위의 염증은 감각 신경을 민감하게 하여 유해한 기계적, 화학적, 열적 자극에 대한 반응 역치를 낮춥니다.109,116,117,118 감각 신경의 말단에는 특정 염증 매개체와 성장 인자를 감지하는 광범위한 수용체가 있으며,119 이러한 수용체의 활성화는 이온 채널(예: Nav1.7, Nav1.8, Nav1.9, TRPV1 및 TRPA1)의 인산화, 게이트 및 상향 조절과 같은 일련의 다운스트림 변화를 유발하여,109 민감화와 추가적인 신경 전달 물질 방출로 이어집니다.109,120 사이토카인(히스타민, TNF, IL-1β, IL-6, IL-17A), 지질 매개체(프로스타글란딘 E2(PGE2), 류코트리엔 B4), 성장 인자(NGF, 뇌 유래 신경 영양 인자(BDNF))는 주로 비만 세포, 호중구, 대 식세포, Th17 또는 γδT 세포에서 생성되며 감각 신경의 민감화에 크게 기여합니다.121 예를 들어, 말단에서 TNFα와 그 수용체(TNFα 수용체 1, TNFR1)의 결합은 Nav1.8 채널을 인산화하여 채널 개방을 촉진합니다.122 요컨대, 월러리안 변성과 염증은 골절 시 말초 신경의 일차적인 반응입니다.

Changes in peripheral nerves during bone repair and regeneration

Bone regeneration completely restores the original microarchitecture and is accompanied by reinnervation. These two seemingly independent processes are tightly intertwined in reality. Using growth-associated protein 43,123 which is more preval‎ent in differentiating and regenerating neurons than in mature neurons,124 or Thy-1,110 a pan-neural gene,125 the changes in peripheral nerves during reinnervation at the fracture site can be clearly observed. The reinnervation process precedes angiogenesis at the early stage of bone repair/regeneration.126,127 Previous studies have reported that ectopic sprouting of sensory and sympathetic nerve fibers after bone trauma greatly contributes to the hyperinnervation of all the compartments at the fracture site.123,127,128,129 Moreover, researchers concluded that an adequate density of innervation was the prerequisite for initiating regeneration in salamanders,22,130 indicating that hyperinnervation after bone fracture may be required for regeneration. During callus formation and maturation, peripheral nerves sprout while the bone matrix is deposited, gradually reduced, and finally restricted to the outer fibrous capsule of the hard callus when injured nerves are trimmed.123 Both CGRP+ and TH+ spouting nerve fibers can participate in reinnervation, and CGRP+ nerve fibers contribute the most.123,129,131 Reinnervation of bone has also been confirmed by findings in calvarial bone defect regeneration.132 After bone repair, the PNS fibers in bone typically return to physiological levels. However, in fracture nonunion, hyperinnervation remains around the bone, periosteum, cortical bone, and bone marrow.128 At present, the remaining hyperinnervation is viewed as a pathological state associated with chronic pain.133 These observations suggest an interdependent relationship between bone regeneration and PNS regeneration after bone fracture.

뼈 회복 및 재생 중 말초 신경의 변화

뼈 재생은 원래의 미세 구조를 완전히 복원하고 재신경화를 동반합니다. 독립적으로 보이는 이 두 가지 과정은 실제로는 서로 밀접하게 얽혀 있습니다. 성숙한 신경세포보다 분화 및 재생 중인 신경세포에 더 많이 존재하는 성장 관련 단백질 43,123 또는 범신경 유전자 Thy-1,110을 사용하면 골절 부위에서 재신경화가 진행되는 동안 말초 신경의 변화를 명확하게 관찰할 수 있습니다. 재신경화 과정은 뼈 회복/재생의 초기 단계에서 혈관 신생에 선행합니다.126,127 이전 연구에 따르면 골 외상 후 감각 및 교감 신경 섬유의 이소성 발아가 골절 부위의 모든 구획의 과신경화에 크게 기여한다고 보고되었습니다.123,127,128,129 또한 연구자들은 적절한 신경 밀도가 도롱뇽에서 재생을 시작하기 위한 전제 조건이라고 결론지었는데,22,130 이는 골절 후 과신경화가 재생에 필요할 수 있음을 시사합니다. 캘러스 형성 및 성숙 과정에서 말초 신경은 골 기질이 침착되는 동안 싹이 트고 점차 감소하며, 손상된 신경이 다듬어지면 최종적으로 단단한 캘러스의 외부 섬유 캡슐로 제한됩니다.123 CGRP+ 및 TH+ 분출 신경 섬유 모두 재신경화에 참여할 수 있으며 CGRP+ 신경 섬유가 가장 많이 기여합니다.123,129,131 뼈의 재신경화는 종골 결손 재생에서도 발견되었습니다.132 뼈 회복 후 뼈의 PNS 섬유는 일반적으로 생리적 수준으로 되돌아갑니다. 그러나 골절 불유합의 경우 뼈, 골막, 피질골 및 골수 주변에 과신경이 남아 있습니다.128 현재 남아 있는 과신경은 만성 통증과 관련된 병리 상태로 간주됩니다.133 이러한 관찰은 골절 후 뼈 재생과 PNS 재생 사이에 상호 의존적인 관계가 있음을 시사합니다.

Peripheral nerve regulation of bone regeneration

Physiological innervation of different compartments and the intertwined schedule of regeneration make the PNS a strong candidate for the regulation of bone regeneration. With continuous research on the role of the PNS in bone regeneration, the emerging importance of the PNS echoes the well-known role of nerves in limb regeneration. Early relevant denervation experiments provided insight into this phenomenon. Sciatic nerve resection results in defective callus formation in rats and rabbits.25 Inferior alveolar denervation impairs regeneration of the mandibular bone defect in rats.26 The administration of high-dose capsaicin to destroy capsaicin-sensitive sensory nerves decreases Mg2+-mediated promotion of fracture healing.108 Similarly, disruption of TrkA signaling blunts angiogenesis and delays callus formation in mice.124 Knockout of GGRP in mice inhibits bone healing.134 Sympathectomized mice have delayed cartilaginous callus formation and callus mineralization.135,136 The findings of these in vitro and animal experiments are compatible with clinical observations of bone development. Congenital insensitivity to pain with anhidrosis, which is a hereditary neurodevelopmental disorder caused by mutations in TRKA,134 is associated with short stature and delayed fracture healing.137 In regard to unsuccessful bone regeneration, initial injury of the nerve or vasculature may be associated with a secondary operation after nonunion repair.136 The nonhealing area in spondylolisthesis patients has been shown to coincide with the region lacking innervation.138 In addition, postoperative absorption has been a challenge in the use of vascularized iliac bone to reconstruct the jaw,139 and 10 out of 22 patients who were treated with neurorrhaphy between the ilioinguinal nerve and the inferior alveolar nerve or auricular nerve during the reconstruction of the mandibular bone exhibited reduced bone absorption.140 These clinical observations indicate the involvement of peripheral nerves in regulating osteogenesis from the embryonic phase to adulthood.

뼈 재생의 말초 신경 조절

여러 구획의 생리적 신경 분포와 서로 얽혀 있는 재생 일정은 PNS를 뼈 재생을 조절하는 강력한 후보로 만듭니다. 뼈 재생에서 PNS의 역할에 대한 지속적인 연구와 함께 PNS의 중요성이 부각되면서 팔다리 재생에서 신경의 잘 알려진 역할이 재조명되고 있습니다. 초기의 관련 탈신경 실험은 이 현상에 대한 통찰력을 제공했습니다. 좌골 신경 절제는 쥐와 토끼에서 결함이 있는 캘러스 형성을 초래합니다.25 열등한 폐포 탈신경은 쥐의 하악골 결손 재생을 손상시킵니다.26 고용량 캡사이신을 투여하여 캡사이신에 민감한 감각 신경을 파괴하면 Mg2+ 매개 골절 치유 촉진이 감소합니다.108 유사하게, TrkA 신호의 중단은 생쥐에서 혈관 신생을 둔화시키고 캘러스 형성을 지연시킵니다.124 생쥐에서 GGRP의 녹아웃은 뼈 치유를 억제합니다.134 교감신경 절제 마우스는 연골 캘러스 형성 및 캘러스 미네랄화가 지연되었습니다.135,136 이러한 체외 및 동물 실험의 결과는 뼈 발달에 대한 임상 관찰과 일치합니다. 선천성 통증에 대한 무감각증은 TRKA 돌연변이로 인한 유전성 신경 발달 장애이며,134 저신장 및 골절 치유 지연과 관련이 있습니다.137 뼈 재생 실패와 관련하여 신경 또는 혈관계의 초기 손상은 비유합 수리 후 2차 수술과 관련이 있을 수 있습니다.136 척추 전만증 환자의 치유되지 않는 부위는 신경이 없는 부위와 일치하는 것으로 나타났습니다.138 또한 턱을 재건하기 위해 혈관이 형성된 장골을 사용할 때 수술 후 흡수가 문제가 되어 왔으며,139 하악골 재건 중 장골신경과 하치조신경 또는 귀신경 사이의 신경병증으로 치료받은 22명의 환자 중 10명이 골 흡수 감소를 보였습니다.140 이러한 임상 관찰은 배아기부터 성인이 될 때까지 골 형성을 조절하는 데 말초 신경이 관여한다는 것을 나타냅니다.

Fig. 3

Illustration of possible ways in which the PNS can regulate bone regeneration following trauma. a Structure of peripheral nerves and nerve-resident cells involved in bone regeneration. b The PNS regulates bone regeneration in two main ways: neuropeptides or neurotransmitters and nerve-resident cells. Neuropeptides or neurotransmitters can be secreted by injured and activated nerve fibers. Nerve-resident cells, mainly SCs and endoneurial mesenchymal cells, alter their transcription and translation, changing their ordinary phenotype to a reparative one, which is similar to their precursor cells (these cells have a common origin from NCCs) after nerve injury. Repair SCs can secrete regulatory molecules, such as oncostatin M and PDGF-AA, to promote regeneration, and endoneurial mesenchymal cells in injured nerves differentiate into bone-lineage cells. The development of inflammation, the invasion of newly formed vessels, the differentiation of osteogenesis and osteoclastogenesis are all regulated by these responses of the PNS after bone trauma

PNS가 외상 후 뼈 재생을 조절할 수 있는 가능한 방법의 그림.

a 뼈 재생에 관여하는 말초 신경 및 신경 상주 세포의 구조.

b PNS는 신경 펩티드 또는 신경 전달 물질과 신경 상주 세포의 두 가지 주요 방식으로 뼈 재생을 조절합니다. 신경 펩타이드 또는 신경 전달 물질은 손상되고 활성화된 신경 섬유에서 분비될 수 있습니다. 신경 상주 세포(주로 SC와 신경 내 중간엽 세포)는 신경 손상 후 전사 및 번역을 변경하여 일반적인 표현형을 전구 세포(이러한 세포는 NCC에서 공통적으로 유래)와 유사한 회복 세포로 변경합니다. 복구 SC는 재생을 촉진하기 위해 온코스타틴 M 및 PDGF-AA와 같은 조절 분자를 분비할 수 있으며, 손상된 신경의 신경 내 중간엽 세포는 뼈 계통 세포로 분화합니다. 염증의 발생, 새로 형성된 혈관의 침입, 골 형성 및 파골 세포 형성의 분화는 모두 골 외상 후 PNS의 이러한 반응에 의해 조절됩니다.

The discovery of relevant neuropeptides and their receptors in bone-lineage cells is a cornerstone of their crosstalk with the PNS (Table 1), but how are the regulatory signals transported from neurons to the bone? Although osteocytes, osteoblasts, osteoclasts, and vascular endothelial cells are located in close proximity to free nerve endings,98,141,142 the rarity of these direct connections casts doubt on the hypothesis of synaptic connections, which has not yet been found.141,143,144 It is uncertain whether the effects of PNS fibers on bone regeneration occur in a direct or indirect manner or both. Currently, two main ways whereby the PNS regulates bone regeneration have been proposed, as shown in Fig. 3.

뼈 계통 세포에서 관련 신경 펩타이드와 그 수용체를 발견한 것은 PNS와의 상호 작용의 초석입니다(표 1). 하지만 조절 신호가 뉴런에서 뼈로 어떻게 전달될까요? 조골세포, 조골세포, 파골세포 및 혈관 내피 세포는 자유 신경 종말에 근접해 있지만,98,141,142 이러한 직접 연결의 드물기는 아직 발견되지 않은 시냅스 연결 가설에 의문을 제기합니다.141,143,144 PNS 섬유가 뼈 재생에 미치는 영향이 직접 또는 간접 방식으로 발생하는지 또는 둘 다에서 발생하는지는 불확실합니다. 현재 PNS가 뼈 재생을 조절하는 두 가지 주요 방법은 그림 3 과 같이 제안되었습니다.

Table 1 Expression‎ of receptors involved in PNS-mediated regulation of bone regeneration in corresponding bone cell lineages

Neuro-skeletal regulation during bone regeneration

After bone trauma, nerve activation in bone and nerve regeneration at the injured site occur simultaneously. The upregulation of a wide variety of neuropeptides or neurotransmitters in activated sensory nerves and in the ANS is regulated by signals to the CNS and contributes to shaping the dynamic microenvironment of bone regeneration (Fig. 4). In addition, neurotrophins and axon guidance family proteins, which are highly active during nerve regeneration and are regulated by the PNS and other cells in the bone microenvironment, are also responsible for mediating bone regeneration. Cells in nerves, such as SCs and endoneurial mesenchymal cells, convert to a regenerative phenotype that is more similar to their precursor state. Through paracrine signaling or possible redifferentiation, these transcription-altered cells not only participate in nerve regeneration but also communicate with bone-lineage cells for bone regeneration.

뼈 재생 중 신경 골격 조절

뼈 외상 후에는 뼈의 신경 활성화와 손상 부위의 신경 재생이 동시에 일어납니다. 활성화된 감각 신경과 ANS에서 다양한 신경 펩타이드 또는 신경 전달 물질의 상향 조절은 CNS로의 신호에 의해 조절되며 뼈 재생의 역동적인 미세 환경을 형성하는 데 기여합니다(그림 4). 또한 신경 재생 중에 매우 활성화되고 뼈 미세 환경의 PNS 및 기타 세포에 의해 조절되는 뉴로트로핀과 축삭 유도 계열 단백질도 뼈 재생을 매개하는 역할을 담당합니다. SC 및 신경 내 중간엽 세포와 같은 신경 세포는 전구체 상태와 더 유사한 재생 표현형으로 전환됩니다. 파라크린 신호 또는 재분화 가능성을 통해 이러한 전사 변형 세포는 신경 재생에 참여할 뿐만 아니라 뼈 재생을 위해 뼈 계통 세포와 소통합니다.

Fig. 4

Illustration showing how PNS nerve fibers regulate bone regenerative processes following injury. The basic regeneration processes are represented by blue arrows. Neuropeptides or neurotransmitters positively or negatively regulate osteoblastic differentiation in MSCs, osteoclastogenesis in monocytes, tube formation by endothelial cells, type switching in macrophages and the recruitment of immune cells during the inflammatory phase of bone regeneration. Dedifferentiated SCs and endoneurium mesenchymal precursor cells contribute to new bone formation via direct osteoblastic differentiation or indirect secretion to stimulate the differentiation of MSCs. Red arrowheads represent a stimulatory effect, while green flatheads represent an inhibitory effect. Green boxes contain stimulative neuropeptides or neurotransmitters for the corresponding process, and blue boxes contain suppressive neuropeptides or neurotransmitters. “?” indicates that more reliable evidence is needed.

PNS 신경 섬유가 부상 후 뼈 재생 과정을 조절하는 방법을 보여주는 그림. 

기본적인 재생 과정은 파란색 화살표로 표시되어 있습니다. 신경 펩타이드 또는 신경 전달 물질은 MSC의 조골 세포 분화, 단핵구의 파골 세포 형성, 내피 세포에 의한 관 형성, 대 식세포의 유형 전환 및 뼈 재생의 염증 단계에서 면역 세포의 모집을 긍정적으로 또는 부정적으로 조절합니다. 분화된 SC와 내막 중간엽 전구세포는 직접 조골세포 분화 또는 간접 분비를 통해 새로운 뼈 형성에 기여하여 MSC의 분화를 자극합니다. 빨간색 화살촉은 자극 효과를, 녹색 납작한 화살촉은 억제 효과를 나타냅니다. 녹색 박스는 해당 과정에 대한 자극성 신경펩타이드 또는 신경전달물질을 포함하고, 파란색 박스는 억제성 신경펩타이드 또는 신경전달물질을 포함하고 있습니다. “?"는 보다 신뢰할 수 있는 증거가 필요함을 나타냅니다.

CGRP calcitonin gene‐related peptide, SP substance P, NE norepinephrine, NPY neuropeptide Y, VIP vasoactive intestinal peptide, NGF nerve growth factor, BDNF brain-derived neurotrophic factor, NT-3 neurotrophin-3, Sema3A Semaphorin 3A, Sema3E Semaphorin3E, Sema4D Semaphorin4D

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CGRP

CGRP, which is the major neurotransmitter of sensory nerves, is produced by alternative splicing of the CALC gene.145,146 CGRP is transcribed from different regions in the CALC gene and exists in two forms: αCGRP and βCGRP. βCGRP is mainly found in the enteric nervous system,70,147 which is consistent with the observation that αCGRP is the main cause of elevated levels of CGRP in serum after the fracture in mice.148 The CGRP receptor is a heterodimer of calcitonin receptor‐like receptor (CRLR), which is a G‐protein coupled receptor (GPCR), and its coreceptor, receptor activity‐modifying protein 1 (RAMP1).70 CGRP is increased in injured bone tissues, and the expression‎ of its receptor also increases at the early stages of bone regeneration.107,148 The administration of CGRP promoted the migration of bone marrow mesenchymal stem cells (BMSCs) to the fracture site and osteogenic differentiation in rats.149 Disruption of CGRP signaling with receptor antagonists such as CGRP 8–37 and nonpeptide CGRP antagonists (BIBN4096BS) or with short interfering RNA significantly inhibited new bone formation.107,149 Further studies demonstrated that CGRP activated the cAMP/protein kinase A (PKA) signaling pathway and subsequently inhibited BMSC apoptosis and promoted BMSC proliferation and osteogenic differentiation by enhancing Wnt/β‐catenin in vitro.150,151 The overexpression‎ of RAMP1 in BMSCs enhances the osteogenic differentiation of BMSCs, while blocking Yap1 blocks this effect, indicating that CGRP can promote BMSC differentiation via the Hippo/Yap pathway.152 Impairment of cartilaginous callus remodeling and callus bridging in CGRP−/− mice is linked to the low expression‎ of key mediators (adiponectin, adipocyte protein 2, and adipsin) of the PPARγ pathway,134 the inhibition of which impairs the osteogenesis effect of BMP-2.153 CGRP also has a negative effect on osteoclastogenesis by suppressing osteoprotegerin (OPG) production in osteoblasts.154 Preclinical use of electrical stimulation of lumbar DRGs can promote the release of CGRP and effectively enhance femoral fracture healing, providing an innovative strategy for further clinical use.155

Substance P

SP is another major neurotransmitter that is released by activated sensory nerves and is usually released with CGRP.153 SP is encoded by the tachykinin precursor 1 (TAC1) gene and binds to its receptor neurokinin‐1 receptor (NK‐1R) to regulate target cells. NK-1R has been identified in BMSCs,135 osteoblasts and osteoclasts.156,157,158 SP+ nerve fibers are increased following a fracture or bone defect,108,159 as is the expression‎ of SP in injured bone.160 SP has been reported to improve the osteoblastic differentiation of BMSCs and MC3T3-E1 cells by activating the Wnt/β-catenin signaling pathway.161,162 Furthermore, SP embedded on titanium substrates can also promote BMSC recruitment during bone healing.163 On the other hand, blocking NK-1R reduces the expression‎ of osteocalcin and collagen 1A2 and 2A1 during bone regeneration, resulting in significantly impaired biomechanical strength.164

While having an impact on osteogenesis differentiation, SP also modulates osteoclastogenesis. SP can promote osteoclastogenesis independently of RANKL by inducing NF‐κB in osteoclast precursors165 or by stimulating osteoblast lineage cells to produce RANKL.158 This effect has been reported to be dose dependent: SP promotes osteoblast differentiation and matrix mineralization when the concentration is greater than 10−8 mol·L−1 and suppresses these processes at less than 10−8 mol·L−1.135 Investigation of the regenerative process of TCA1−/− mice provided new evidence. Compared to bone regeneration in WT mice, TAC1−/− mice showed a decrease in the total area of cartilaginous soft callus tissue, reduced numbers of osteoclasts and osteoblasts at the fracture site, and impaired resistance to torsional failure load.135 Furthermore, recent observations in ovariectomized TAC1−/− mice contradict previously published results with regard to the hypertrophic chondrocyte area, but the number of osteoclasts in the fracture site was consistent with the final outcome.166 Whether these discrepancies are the result of ovariectomy is not yet clear.

Norepinephrine

NE is an important neurotransmitter that is released by noradrenergic nerves, which are mainly postganglionic fibers of the SNS. There are two forms of the receptor, the α‐adrenergic (α‐AR) and β‐adrenergic receptors (β‐AR), each containing many subtypes.89 These receptors have been observed in various bone-lineage cells.144,167,168,169,170 High sympathetic tone increases epinephrine, which can be detected in urine, resulting in the suppression of osteoblast activity, as evidenced by abnormal morphology and reduced Ki67 expression‎ in osterix+ cells.171 A β2-AR antagonist has been shown to rescue these changes, highlighting the negative effect of NE on osteoblastic differentiation.171 NE may also inhibit the proliferation of hBMSCs through β2-AR-induced phosphorylation of ERK1/2 and PKA.172 In addition, NE induces osteoclastogenesis by activating RANKL/OPG.173,174 The nxxxxonselective β‐AR blocker propranolol has been shown to enhance bone healing in rats;175 interestingly, administration of propranolol to posttraumatic stress disorder (PTSD) mice with femur fractures ameliorated the defect in new bone formation.176 However, given that the effect of nxxxxonselective β-AR blockade differs greatly between mice and humans in the context of bone metabolism,177 further evidence on the effects of NE and β‐AR on human bone regeneration is still needed. For α‐AR, DNA synthesis in BMSCs is reported to increase in rats via α1-AR.178 The administration of phenylephrine, a nonspecific α1-AR agonist, promotes the proliferation of MC3T3-E1 cells by increasing the expression‎ of the transcription factor CCAAT/enhancer-binding protein δ (Cebpd).169 Its detailed role in bone regeneration requires further elucidation.

Significantly, α- and β-ARs are GPCRs, and downstream binding to α-AR decreases cAMP and subsequently inhibits PKA, while binding to β-AR induces the opposite effects. However, the binding affinity of NE largely depends on its concentration:179 at concentrations less than 10−8 mol·L−1, NE preferentially binds to α‐AR, while at concentrations higher than 10−6 mol·L−1, β‐AR is preferred. The concentration of NE in bone marrow ranges from 10−9 mol·L−1 (physiological) to 10−5 mol·L−1 (pathological).179,180 Therefore, the effect of NE during the process of bone regeneration may vary dynamically depending on the stage of the regenerative process.

Acetylcholine

Identifying the involvement of PSNS in the skeletal system draws attention to the role of ACh in bone regeneration. As previously described (Fig. 2b), ACh can function as a transmitter in the PSNS by binding to nicotinic (nAChRs) and muscarinic acetylcholine receptors (mAChRs),68 both of which have been found in bone-lineage cells.181,182,183 Past studies demonstrated that ACh promoted osteoblastic proliferation81,182 but had little effect on osteoblastic differentiation.81 Unexpected negative effects on alkaline phosphatase (ALP) activity in osteoblasts have also been reported.181 An increase in bone resorption was observed in α2nAChR−/−mice through increased osteoclast numbers, and nAChR agonist administration increased apoptosis.81 Furthermore, RANKL-induced Ca2+ oscillation, the well-established osteoclastogenesis process,184 is inhibited by activation of nAChR, and subsequent weakened Ca2+-NFATc1 signaling leads to a negative regulatory effect on osteoclastogenesis.185 Donepezil, an acetylcholinesterase inhibitor (AChEI) that suppresses ACh degradation and increases the concentration of ACh, impairs bone healing by decreasing immune cell infiltration during the inflammation phase and reducing new bone formation.186 In a retrospective cohort study on Alzheimer’s disease patients with hip fracture, AChEI users had better radiographically observed union at the fracture site; better bone quality; and fewer healing complications, such as infection and delayed healing, than nonusers.187 Notably, the specific functions of the mAChR subtypes in the skeletal system should be clarified.81,182,188 Moreover, the M3 muscarinic acetylcholine receptor (M3AChR) in nerves plays an important role in bone metabolism.188

Neuropeptide Y and vasoactive intestinal peptide

The receptors for NPY are GPCRs, and according to a rodent study, two of the five types (Y1 and Y2) are associated with the regulation of the skeletal system.189 Y1 has been observed in osteoblasts, while Y2 is located in the brain.190 Previous studies have demonstrated that NPY decreases cAMP levels in osteoblasts, impairing mineralization,190 while the administration of a Y1 antagonist promotes BMSC osteoblastic differentiation.191 Similarly, BMSCs isolated from Y1-silenced mice exhibited increased ALP activity and calcium nodule formation with increased expression‎ of COL1, OCN, and Runx2, further illustrating the effect of NPY on the proliferation and apoptosis of BMSCs.192 The use of the Y1 receptor antagonist PD160170 on the femur improved the healing of bone defects.193 Recently, osteocytes from aging mice were shown to secrete NPY at high levels to induce adipogenesis in BMSCs, which is consistent with previous investigations.194

Vasoactive intestinal peptide (VIP), which is produced by enteric neurons, is also released by other peripheral nerves195,196 and is mediated by three types of GPCRs (VPAC1, VPAC2, PAC1).196 VIP can promote BMSC osteogenic differentiation through the Wnt/β‐catenin signaling pathway in rats.197 Although reported to inhibit BMSC proliferation,198 VIP-containing MeHA hydrogels increase the expression‎ of vascular endothelial growth factor (VEGF), ultimately improving the healing of rat skull defects.197 Similarly, impaired bone regeneration after chemical sympathectomy can be rescued with VIP treatment, resulting in an increase in mineralized callus and improved callus bridging.199

Neurotrophins

Neurotrophins are crucial for neuronal development and normal function and are involved in the formation of almost all neural circuits.200 Four types of neurotrophins have been discovered in mammals: NGF, BDNF, neurotrophin-3 (NT-3), and neurotrophin-4/5 (NT-4/5). All types can bind to the low-affinity receptor p75NTR and to the specific high-affinity tropomyosin-related kinase (TRK).200,201 These factors function mainly through TRK; NGF binds to TrkA, BDNF and NT-4/5 bind to TrkB, and NT-3 binds to TrkC.201 Neurotrophins have been shown to be involved in bone regeneration through relevant receptors in recent years, especially NGF, BDNF, and NT-3.202,203,204,205,206

NGF is upregulated at the very early postfracture stage.123 In vitro, NGF can promote osteoblastic differentiation207 and has an antiapoptotic effect on MC3T3-E1 cells.208 A recent study demonstrated that most cells located in the periosteal callus, mainly periosteal/stromal cells and macrophages, were NGF+ cells during callus ossification, and the number of cells decreased during mineralization,123 which is consistent with the reinnervation of the injured PNS as previously described. Chemical disruption of NGF-TrkA signaling impairs the regeneration of the PNS and bone by reducing osteoblast activity and delaying callus mineralization.123 The administration of exogenous NGF improved healing in rabbit mandible fractures by increasing BMP-9 and VEGF levels.209 Similarly, entochondrostosis is enhanced by β-NGF supplementation, as evidenced by the increased expression‎ of marker genes, such as Ihh, Alpl, and Sdf-1, which are associated with endochondral ossification. Local injection of NGF consequently promotes bone regeneration with deceased cartilage and increased bone volume.210 However, there are also controversial results suggesting that blockade NGF or TrkA by neutralizing antibodies reduces fracture-induced pain but has no side effect on bone healing as changes on biomechanical properties and callus formation and maturation are not observed in mice.211,212 A recent study showed that NGF has been used to treat traumatic nonunion in clinical trials, showing encouraging outcomes in promoting callus formation and fracture healing.213 A high-quality clinical trial with a large sample size is still needed to verify the effect of anti-NGF agents on bone pain and regeneration.

BDNF, which is critical in the development of the nervous system,201 was found in the brain after the discovery of NGF. BDNF also has an effect on the regulation of bone regeneration and can be released by inflammation-activated TrkA+ nerve fibers after bone trauma.214 BDNF can promote the proliferation and differentiation of hBMSCs.215 The promotion of bone regeneration by BDNF is achieved through the upregulation of integrin β1 via TrkB‐mediated ERK1/2 and AKT signaling.216 BDNF also enhances the production of RANKL by hBMSCs, contributing to osteoclastogenesis.217 These seemingly conflicting effects on bone may be due to the epigenetic regulation of BDNF transcription, whereby different physiological or pathological conditions induce alternative splicing and polyadenylation.201

The role of NT-3 in bone regeneration has been recently noted. The upregulated expression‎ of NT-3 and its receptor TrkC has been verified during bone regeneration.206 By enhancing the expression‎ of BMP-2 through Erk1/2 and Akt phosphorylation, NT-3 promotes osteogenesis in rat bone marrow stromal cells in vitro.206 Treatment with NT-3 during tibial fracture regeneration in rats promoted the expression‎ of BMP-2 and TGF-β1, resulting in increased maximum load capacities.218 Systemic administration of NT-3 reduced the bone volume at the defects through immunoneutralization.206 It has been demonstrated that NT-4/5 is involved in pulp cell differentiation and regulating the function of periodontal ligament cells,219,220 but the association of NT-4/5 with bone regeneration remains unclear.

Axon guidance family proteins

Axon guidance family proteins were initially identified during the development of the nervous system and provide attractive or repulsive cues to nerves during development or regeneration. Axon guidance family proteins guide the nerve to reach the correct target.221,222 Different from the previously described molecules, many members of this family and their ligands are membrane-bound. Class 3 semaphorins, a secreted class of axon guidance proteins, have long been linked to bone regulation. Semaphorin 3A (Sema3A), the receptor Nrp1, and the coreceptor Plxna1–3 have been found in bone tissue. Sema3A derived from sensory nerves has independent effect on bone by expediting innervation of sensory nerves and Sema3A promotes osteoblastic differentiation, enhances new bone formation, and inhibits RANKL-induced osteoclastogenesis via the Rac1 and Wnt/β-catenin pathways.223,224 The administration of Sema3A improved the formation of new bone in a similar way during calvarial defect healing in rats.225 The promotion of tibial fracture healing by Sema3A has also been observed in osteoporotic rats.226 Other Semaphorin 3 proteins also have effects on bone. Sema3E may inhibit the migration of osteoblasts and suppress the osteoclastogenesis of bone marrow-derived macrophages (BMMs).227 Furthermore, Sema4D has been demonstrated to exhibit negative effects on osteogenesis. By binding to the receptor Plexin-B1 on osteoblasts, osteoclast-derived Sema4D inhibits insulin-like growth factor-1 signaling, as well as migration, and consequently impairs bone formation.228 Disrupting Sema4D signaling increases the regeneration of defects in osteoporotic mice.229

The remaining classical axon guidance family proteins include ephrins, slits, and netrins. Erythropoietin-producing hepatocellular carcinoma (Eph) receptor tyrosine kinases and their ligands, ephrins, are important in bone formation. When Eph receptors on nerves mediate signal transduction, ephrins can also elicit a reverse signal in ephrin-expressing cells,230 such as bone-lineage cells (Table 1).231,232,233,234 Knocking out ephrin-B1 or -B2 in osteogenic progenitors significantly inhibited fracture healing.235,236 SLIT3 can promote the proliferation and migration of osteoblasts while suppressing the maturation of osteoclasts.237 Netrin-1 is involved in osteoclast differentiation,238 and as a part of bone-lineage cells that coordinates the PNS, osteoclasts can produce netrin-1 to guide the PNS.239 Studies on the effects of slits and netrins on bone-lineage cells during bone regeneration are still lacking. Moreover, a large number of axon guidance family proteins are theoretically needed to assist nerve growth, but very few new members have been discovered, such as draxin and phosphatidyl-β-D-glucoside.222

PGE2 signaling

The initial inflammatory phase drives bone regeneration, during which inflammatory mediators are produced to initiate a cascade of bone repair. PGE2 is a lipid mediator that is a member of the prostaglandin family. The key enzymes associated with PGE2 biosynthesis are prostaglandin E2 synthase-1 (mPGES-1) and COX. Inflammation-induced COX-2 expression‎ contributes most to the catalysis of arachidonic acid into PGE2.240 PGE2 functions by binding with the receptors EP1–4, which are GPCRs that activate downstream effectors.240 PGE2 activates the EP4 receptor on sensory nerves and signals to the hypothalamus, downregulating sympathetic tone by activating the transcription factor cAMP response element-binding protein. Consequently, the adipogenic differentiation of BMSCs is inhibited, and osteoblastic differentiation is enhanced. Disruption of PGE2/EP4 signaling significantly impairs bone regeneration.171,241 Clinical administration of NSAIDs to reduce pain delays fracture healing and increases bone nonunion, providing further supporting evidence.242 Similarly, treatment with opiates, another effective class of analgesic drugs whose receptors are widely expressed on central and peripheral nerves,243 also leads to impaired bone healing.244,245 These clinical observations complicate pain management after the bone fracture, urging more intensive studies to support clinical strategies. Given the critical role of the inflammatory environment after bone trauma, this pathway holds great importance in the regenerative process. Although PGE2 is not released by neurons, neuro-skeletal regulation is initiated by PGE2. Moreover, direct effects of PGE2 on bone-lineage cells have also been reported.246,247,248 PGE2 signaling indicates that sensory and sympathetic nerves act as a circuit, and the collaboration of sensory and sympathetic nerves as parallel efferent regulators to maintain hematopoietic stem cells in BM niches has also been reported recently.249 The full picture of the relationship between sensory and sympathetic nerves in bone regeneration has yet to be revealed. Great progress has been made in identifying the roles of neuropeptides and neurotransmitters in bone regeneration, but the exact mechanisms whereby neuropeptides and neurotransmitters regulate specific bone regenerative processes are still under investigation (Fig. 5).

Fig. 5

The diagram shows the possible signaling pathways of three representative neuropeptides (CGRP, BDNF, and Sema3A) that regulate bone formation. a Calcitonin gene‐related peptide (CGRP) is the main neuropeptide secreted by sensory nerves whose receptor is a G‐protein coupled receptor (GPCR). CGRP binds to the RAMP1-CALCRL complex and activates coupled Gαs subunits, which elevates the intracellular cAMP concentration and subsequently activates PKA. PKA inhibits the phosphorylation of β-catenin by GSK-3β. Unphosphorylated β-catenin translocates into the nucleus, where it associates with TCF/LEF transcription factors. Meanwhile, PKA activates CREB, which translocates into the nucleus and forms a homodimer or heterodimer that binds to the target gene. b Brain-derived neurotrophic factor (BDNF) is an important member of the neurotrophin family. BDNF binding to TrkB leads to the autophosphorylation of TrkB, which activates the PI3K/AKT and MEK/ERK pathways. RUNX2 is activated by the latter signaling pathway and upregulates the downstream molecule osterix to promote bone formation. The activation of ERK or AKT may contribute to the increased expression‎ of integrin-β1, which is associated with migration. c Sema3A inhibits osteoclastogenesis in macrophages. Semaphorin 3A (Sema3A) is a secreted protein in the axon guidance protein family. Sema3A binds to its receptor PlxnA1–Nrp1 to inhibit the formation of the PlxnA1–TREM2–DAP12 complex, which can respond to ligands, such as Sema6D, to dephosphorylate NFATc1, thus inducing the transcription of osteoclast-specific genes. On the other hand, Sema3A activates RhoA, inhibiting BMM migration to prevent osteoclastogenesis. “?” indicates that more direct evidence is needed

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SCs and endoneurial mesenchymal cells

SC secretion has been given the greatest attention in peripheral nerve regeneration.8 Paracrine effects also contribute to the function of SCs during bone regeneration. Transplantation of SCs into the denervated mandibular defects of mice effectively mitigates impaired defect regeneration, resulting in significantly increased bone formation.25 PDGF-AA, oncostatin M, and parathyroid hormone have been shown to promote bone formation following the implantation of SCs in denervated mice.25 The paracrine effect is also substantiated by the observation that conditioned medium from SCs promoted the proliferation and migration of BMSCs and improved fracture healing.250 Exosomes derived from SCs showed a similar promoting effect on BMSCs and bone regeneration.251

Furthermore, a developmental link between the nervous and skeletal systems through SCs has been established.252 SC precursors (SCPs) detach from nerve fibers and differentiate into chondrocytes and mature osteocytes.253 SCs detach from injured nerves and dedifferentiate, exhibiting a phenotype that mimics that of stem cells. Using a clonal color-coding technique to trace peripheral glia showed that SCPs and SCs were dormant NCCs that could be recruited from injured nerves.253 In addition, SC-derived dental MSCs can ultimately differentiate into odontoblasts, contributing to tooth regeneration after damage.253 Whether adult SCs directly contribute to bone formation in other parts of the skeletal system is a question that needs further investigation.

As previously described, cells reside in peripheral nerves that actively participate in regeneration (Fig. 3a). Recent single-cell RNA sequencing identified the cells in nerve fibers: SCs, fibroblasts, immune cells, and vasculature-associated cells.254 SCs and endoneurial fibroblasts are believed to be the main cells involved in PNS regeneration.254 A recent experiment identified a group of PDGFRα+ mesenchymal cells, including NCCs, in the endoneurium that displayed characteristics of mesenchymal precursor cells and could dramatically proliferate and differentiate into osteoblasts in vitro and in vivo after nerve injury, promoting regeneration of the digit tip.55

Neuropeptide interactions are noteworthy, and communication between CGRP and SP has also been reported. Bisphosphonates (BPs), which are typically used to treat certain bone diseases, can impair bone regeneration in the jaw by inhibiting osteoclastic bone resorption.255 BPs disturb the neuropeptide balance of CGRP and SP by decreasing CGRP levels and increasing SP levels in the callus. However, the administration of CGRP or SP alone had no effect on the BP-mediated decrease in a macrophage-like cell line (RAW 264.7 cells) in vitro, while concomitant application reduced toxicity.256 The ratio of CGRP to SP is tightly correlated with BP administration.256 SP or CGRP alone promotes BMP-2 signaling in MC3T3 preosteoblasts, but when combined, these factors inhibit osteogenic differentiation.257

It should be noted that many neuropeptides and neurotransmitters released by the PNS after bone trauma can also be produced by nonneuronal cells, such as osteoblast-derived CGRP,258 osteocyte-derived SP,108 osteocyte-derived NPY,194 and callus-derived NGF.259 In particular, macrophage-derived NGF stimulates the ingrowth of skeletal sensory nerves as a key mediator of cranial bone regeneration.132 These factors could function as supplements to neuro-skeletal regulation or via a feedback loop, but the exact effect remains to be clarified. Therefore, conclusions on the function of the PNS in skeletal regeneration should be made with caution. The increased production of neuropeptides during bone healing is shown in Fig. 6, showing differential distributions in the inflammatory, soft/cartilaginous callus, hard/bony callus, and remodeling phases. These bioactive molecules produced by bone-lineage cells during regeneration will not only act on the PNS but also the vasculature and immune system and coordinate bone regeneration processes.

Fig. 6

Increased production of neuropeptides in bone healing. Various neuropeptides (NGF, BDNF, CGRP, SP, NPY, and Sema3A) are differentially distributed during the four corresponding phases (inflammatory, soft/cartilaginous callus, hard/bony callus, and remodeling) of bone healing with blood vessel and nerve regeneration. Cells (BMSCs, osteoblasts, macrophages, osteoclasts, and chondrocytes) listed in the relevant boxes have been identified as targets of specific neuropeptides during bone regeneration

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Neurovascular interactions in bone regeneration

The vasculature develops prior to the nervous system during early embryonic development.260 However, studies in developing limb skin during later embryonic stages show that the alignment of nerve and blood vessels occurs via mesenchymal intrinsic cues or by blood vessels following the routes of peripheral nerves,261,262,263 which is consistent with observations in the fracture callus in bone repair. Neurovascular interactions have been indicated as early as the embryonic period, when nerves and vessels are guided by shared signals such as NGF, VEGF, and four classic axon guidance family proteins (semaphorins, ephrins, netrins, and slits) and corresponding receptors to their destinations.88 Similar pathfinding is mediated by common molecular cues and wiring patterns between blood vessels and sensory nerves. VEGF is released from sensory nerves or SCs and guides blood vessel formation locally during embryonic development and tissue repair. An association between neurovascular interactions and various pathologies, such as tumors21,264 and osteoarthritis (OA) (see below), has also been noted. Recently, precisely orchestrated neurovascular communication has been indicated in the context of bone regeneration, further verifying and extending the molecular portfolio involved in this interaction.

The anabolic effect of neuropeptides occurs through direct binding to bone-lineage cells and through their effects on endothelial cells. Close contact between sensory neurons and bone marrow-derived endothelial cells in cocultures has been observed.265 The administration of CGRP and SP, which are two important neuropeptides released by sensory nerves, upregulates VEGF, type 4 collagen, and matrix metalloproteinase 2.265 Interestingly, Mg2+ can induce CGRP to phosphorylate focal adhesion kinase, increasing VEGF expression‎ and vessel and bone formation.266,267 CGRP also increases the number of endothelial progenitor cells differentiated from BMSCs in vitro via the PI3K/AKT signaling pathway and promotes blood vessel formation at defect sites in a DO model.268 The role of neurotrophins in neurovascular interactions during bone regeneration has also been reported. Inhibiting NGF/TrkA signaling blunts revascularization during bone regeneration, as shown by reduced numbers of CD31+ vessels within fracture sites.123 Systemic treatment with NT-3 immunoneutralization suppresses vascularization at the injury site, while recombinant NT-3 potentiates the expression‎ of VEGF and CD31 in rat endothelial cells.206 The regulatory effect of osteoblast-derived SLIT3 on level of CD31hiEMCNhi skeletal endothelial cells is mediated by SLIT3/ROBO1 pathway, which actively participate in osteogenesis, promotes bone formation,269 and the common pathway of SLIT3 may contribute to the alignment of the reconstructed nerve fibers and newly formed blood vessels during bone regeneration. In addition, deletion of Slit3 in mice significantly impaired bone regeneration, and intravenous injection of SLIT3 in mice led to improved vascularization of the fracture callus and biomechanical properties.269 SC-conditioned medium can promote the proliferation, migration and tube formation of endothelial cells derived from BM-MSCs.250 Taken together, this evidence suggests that peripheral nerves are closely involved in angiogenesis during bone regeneration, but the questions of when and how this aligned pattern of nerves and blood vessels is recovered in complex but sequential bone regenerative processes remain unanswered.

Neuroimmune interactions during bone repair/regeneration

The nervous system and immune system are traditionally thought to work independently, but the role of the nervous system in the host immune response to infection or injury has led to more new discoveries. The expression‎ of Toll-like receptors, which were previously thought to be specific to the immune system, has been identified on sensory nerve fiber terminals.265,266 The sensitization of sensory nerves in the inflammatory phase during bone regeneration, as described previously, has suggested additional shared molecules, such as TNF, IL-1β, and IL-17A.121 The nervous system communicates with the immune system through neurotransmitter receptors, such as muscarinic and nicotinic acetylcholine receptors and α- and β-adrenergic receptors, which usually act on the nervous system but have also been identified on macrophages, dendritic cells, T and B lymphocytes, and even endothelial cells.267 The concept of the neuroimmune cell unit, which refers to a place in which immune and neuronal cells are present and closely communicate, provides further clarity.270

Emerging studies on neuroimmune regulation in bone regeneration have focused on the phenotypic switch from proinflammatory M1 to regenerative M2 macrophages. Macrophages are involved in all bone regenerative processes, but the underlying mechanisms that control the switch are still not clear, despite studies in this field.271,272 The axon reflex may contribute to the neuroimmune interaction in which sensory nerves initiate the transmission of neural signals at the fracture site, and then this neuronal activation reverses to local axonal terminals before being received by the CNS. This will increase the release of neuropeptides. Receptors of SP and CGRP have been detected on mouse BMMs.158,273 After M1 activation induced by lipopolysaccharide and IFN-γ, BMMs harvested from CGRP-deficient mice showed higher expression‎ of the M1 macrophage marker CD86 and lower expression‎ of the M2 macrophage marker CD206 than BMMs from wild-type mice, and the expression‎ of M1-associated factors, such as TNF-α, iNOS, and IL-1, was also increased. Supplementation of CGRP in CGRP-deficient BMMs in vitro reversed these changes.274 CGRP lentiviral vector transfection into CGRP−/− mice promoted the expression‎ of M2-associated markers, such as Arg1 and CD206, in recruited macrophages at the injury site after tooth extraction.274 Moreover, inferior alveolar nerve transection prior to tooth extraction increased the number of recruited neutrophils and reduced the cellular elongation of macrophages, which is associated with the M1 phenotype,275 creating a proinflammatory environment.276 Implantation of CGRP-loaded microbeads into the socket after tooth exaction increased the expression‎ of IL-10 and suppressed TNFα expression‎ in macrophages. Local macrophage blocking by anti-F4/80 antibodies virtually eliminated the previous CGRP-induced effect.276 Recent work shows that CGRP can regulate the secretion of many osteogenic factors in M2 macrophages and promote the osteogenic differentiation of MSCs by activating p-Yap1 in M2 macrophages.277

The CNS mediates reflexes in which responses generated in the CNS travel down to the autonomic nerve fiber terminals. In a clinically relevant mouse model of PTSD, mice have increased numbers of Ly6G+ neutrophils in the fracture hematoma and later callus, and this effect could be ameliorated by treatment with propranolol to improve impaired fracture healing.176 Postoperative administration of donepezil significantly lowers the infiltration of lymphocytes and macrophages but hinders new bone formation.186 These results indicate that ANS regulates recruitment in the inflammatory phase of bone regeneration. Moderate inflammation in bone regeneration has been shown to be necessary for bone regeneration. The observation of neuroimmune interactions in bone regeneration provides initial evidence for a new immune regulator in the skeleton. However, these results are far from clarifying the cellular or molecular mechanisms of neuroimmune cell interactions and the specific role of this interplay during bone regeneration.

The aforementioned observations are partly consistent with the neuroimmune regulation seen in other organs. In collaboration with macrophages, CGRP can regulate the activation of PKA, reduce TNF-α production, and induce the expression‎ of IL-10 in skin wounds.109 TRPV1+ nerves suppress immune activity by releasing CGRP.278 Other neuropeptides associated with neuroimmune regulation, including SP and VIP, have also been identified in other physiological or pathological processes and are well documented.109,120 The necessity of the “nerve, immune, bone” triad is demonstrated by the association between injured nerves, macrophage-derived NGF, and bone regeneration.132 Further examination of neuroimmune regulation in the unique bone niche should continue.

Participation of peripheral nerves in other bone disorders

A large body of preclinical data suggests multiple functions of peripheral nerves in bone pathophysiological conditions, including regenerative processes after injury. Peripheral nerves have been suggested to participate in osteoporosis, OA, bone-related tumors (especially bone metastasis),279 and bone changes related to psychosomatic illness.280,281 The interactions between peripheral nerves and cells in the bone microenvironment in different bone diseases may provide a holistic perspective of the functions of peripheral nerves in bone.

Osteoporosis is usually characterized as an aging-related endocrine disease. In fact, aging can function as a separate process with distinct mechanisms that shape the bone environment, as connecting aged mice to a youthful circulation via heterochronic parabiosis did not improve aging-induced bone loss.282 In addition to senescent cells,283 changes in nerves in bone with aging have also been noted. Leptin, a hormone that is found exclusively in adipose tissue and regulates food intake, has been discovered in hypothalamic centers and is associated with bone loss in obese mice, supporting the close link between the nervous system and bone homeostasis.284 Further research showed that low sympathetic tone resulting from leptin deficiency increased bone mass by regulating the proliferation of osteoblasts and the expression‎ of the osteoclast differentiation factor RANKL in osteoblasts.144,173 Poor peripheral nerve function is also related to lower bone mineral density in patients.285 In osteoporosis and aging-related osteopathic disorders, innervation in bone is impaired. The peroneal nerve, which innervates the lower leg, has increased sympathetic tone in osteoporosis patients and is inversely correlated with bone quality.286 Reduced nerve fibers in the tibia are reported in mice with ovariectomy-induced bone loss and reduced expression‎ of neuronal factors and neurotransmitters.287

OA is a chronic degenerative joint disease characterized by excruciating pain. Increased nerve ingrowth along with newly formed blood vessels in the synovium, osteophytes, and menisci are thought to be associated with OA development and progression.288 OA pain is related to increased sensory nerve fibers, and increased levels of factors such as neuropeptides, VEGF, and NGF may also induce additional pain sensation.288 Osteoclasts can release netrin-1 to induce the growth of sensory nerves and lead to pain in OA.239 Despite many new findings on anti-NGF therapy, the roles of the PNS in rapidly progressive OA and OA with severe joint degeneration require further investigation, as do the serious adverse effects of treatment.289

Conclusion

Bone regeneration is a nerve-dependent process. Continuous discoveries regarding the roles of the PNS in bone repair and regeneration shed light on musculoskeletal biology. Neurotransmitters, neuropeptides, and nerve cell redifferentiation are the main features of neuro-skeletal regulation and have complex molecular mechanisms. New technologies allow in-depth investigations of the interplay of nerves and various cells in the bone at different stages of repair and regeneration.

With further understanding of the multiple functions of nerves in bone homeostasis and regeneration, new therapies to promote nerve-bone interactions will significantly improve bone repair management outcomes and reduce patients’ pain and suffering.

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